Immunisation of large mammals with low doses of RNA

ABSTRACT

RNA encoding an immunogen is delivered to a large mammal at a dose of between 2 μg and 100 μg. Thus the invention provides a method of raising an immune response in a large mammal, comprising administering to the mammal a dose of between 2 μg and 100 μg of immunogen-encoding RNA. Similarly, RNA encoding an immunogen can be delivered to a large mammal at a dose of 3 ng/kg to 150 ng/kg. The delivered RNA can elicit an immune response in the large mammal.

This application is a continuation of U.S. application Ser. No. 17/512,258, filed Oct. 27, 2021, which is a continuation of U.S. application Ser. No. 16/656,929, filed Oct. 18, 2019, which is a continuation of U.S. application Ser. No. 13/808,153, filed Feb. 26, 2013, now U.S. Pat. No. 10,487,332, which is a National Stage Application under 35 U.S.C. § 371 of PCT/US2011/043096, filed Jul. 6, 2011, which claims the benefit of U.S. Provisional Application No. 61/361,794, filed Jul. 6, 2010. The complete contents of the above-listed applications are hereby incorporated herein by reference in their entireties for all purposes.

TECHNICAL FIELD

This invention is in the field of non-viral delivery of RNA for immunization.

BACKGROUND ART

The delivery of nucleic acids for immunizing animals has been a goal for several years. Various approaches have been tested, including the use of DNA or RNA, of viral or non-viral delivery vehicles (or even no delivery vehicle, in a “naked” vaccine), of replicating or non-replicating vectors, or of viral or non-viral vectors.

Various different doses of nucleic acids have been delivered in previous in vivo studies. Reference 1 delivered 50 μg of lipoplexed mRNA or DNA to mice, but also used intraglossal 1 μg and 10 μg doses to analyze luciferase expression in tongue tissue. Reference 2 delivered 12 μg of mRNA encoding influenza virus nucleoprotein to mice. Reference 3 delivered 0.1 μg, 1 μg or 10 μg of self-replicating RNA encoding β-galactosidase to mice. Reference 4 delivered 10 μg of self-replicating RNA encoding rabies virus glycoprotein to mice. Reference 5 delivered a total of 2 μg or 4 μg of DNA encoding influenza haemagglutinin to humans but did not deliver RNA.

Experience with DNA vaccines was encouraging in early work with small animals (e.g., mice) but as the technology moved into large animals (e.g., humans) it became clear that potency decreased. Thus, very high doses would be required (e.g., milligrams rather than micrograms), but clinical-grade DNA is expensive to manufacture.

There remains a need for further and improved nucleic acid vaccines.

DISCLOSURE OF THE INVENTION

According to a first aspect of the invention, RNA encoding an immunogen is delivered to a large mammal at a dose of between 2 μg and 100 μg. As shown below, a dose of 66 μg is immunogenic in calves. An adult cow has a body weight ˜10x that of an adult human and so the inventor has shown that a human dose of 5-10 μg RNA is realistic.

According to a second aspect of the invention, RNA encoding an immunogen is delivered to a large mammal at a dose of 0.1 μg/kg to 1.5 μg/kg. As shown below, a dose of ˜0.94 μg/kg is immunogenic in cattle. Prior art studies have used 100 ng to 10 μg RNA in mice which, with a ˜20 g body weight, is 5 μg/kg to 500 μg/kg.

Thus, the invention provides a method of raising an immune response in a large mammal, comprising administering to the mammal a dose of between 2 μg and 100 μg of immunogen-encoding RNA.

The invention also provides an immunogen-encoding RNA for use in an in vivo method of raising an immune response in a large mammal, wherein the method comprises administering between 2 μg and 100 μg of the RNA to the mammal.

The invention also provides the use of an immunogen-encoding RNA in the manufacture medicament for raising an in vivo immune response in a large mammal, wherein the medicament has between 2 μg and 100 μg of immunogen-encoding RNA per unit dose.

The invention also provides a pharmaceutical composition for a large mammal, comprising between 2 μg and 100 μg of immunogen-encoding RNA per unit dose. In a typical dosage volume of 0.5 ml the concentration of the immunogen-encoding RNA will thus be between 4 μg/ml and 200 μg/ml.

The invention also provides a unit dose of a pharmaceutical composition for administration to a large mammal, wherein the unit dose comprises between 2 μg and 100 μg of immunogen-encoding RNA.

The invention also provides a delivery device (e.g., syringe, nebulizer, sprayer, inhaler, dermal patch, etc) containing a pharmaceutical composition for administration to a large mammal, wherein the composition in the device contains between 2 μg and 100 μg of immunogen-encoding RNA.

The invention also provides a hermetically sealed container containing a pharmaceutical composition for administration to a large mammal, wherein the composition in the container contains between 2 μg and 100 μg of immunogen-encoding RNA.

The invention also provides a method of raising an immune response in a large mammal, comprising administering to the mammal between 0.1 μg and 1.5 μg RNA per kg of the mammal's body weight.

The invention also provides an immunogen-encoding RNA for use in an in vivo method of raising an immune response in a large mammal, wherein the method comprises administering between 0.1 μg and 1.5 μg RNA per kg of the mammal's body weight.

The invention also provides the use of an immunogen-encoding RNA in the manufacture medicament for raising an in vivo immune response in a large mammal, wherein the medicament has between 0.1 μg and 1.5 μg of immunogen-encoding RNA per kg of the mammal's body weight.

Administration

The invention involves administration of RNA to a large mammal. The site of administration will usually be muscle tissue, such as skeletal muscle. Alternatives to intramuscular administration include, but are not limited to: intradermal, intranasal, intraocular, subcutaneous, intraperitoneal, intravenous, interstitial, buccal, transdermal, or sublingual administration. Intradermal and intramuscular administration are two preferred routes.

Administration can be achieved in various ways. For instance, injection via a needle (e.g., a hypodermic needle) can be used, particularly for intramuscular, subcutaneous, intraocular, intraperitoneal, or intravenous administration. Needle-free injection can be used as an alternative.

Intramuscular injection is the preferred way of administering RNA according to the invention. Injection into the upper arm, deltoid, or thigh muscle (e.g., anterolateral thigh) is typical.

The administration site can include both immune cells (such as macrophages, e.g., bone marrow derived macrophages), dendritic cells (e.g., bone marrow derived plasmacytoid dendritic cells and/or bone marrow derived myeloid dendritic cells), monocytes (e.g., human peripheral blood monocytes), etc.) and non-immune cells (such as muscle cells, which may be multinucleated and may be arranged into fascicles, and/or fibroblasts). The immune cells can be present at the time of administration but will usually infiltrate the site after administration. For example, the tissue damage caused by invasive administration (e.g., caused by a needle at the administration site) can cause immune cells to infiltrate the damaged area.

RNA enters the cytoplasm of the immune cells and/or the non-immune cells. Entry can be via endocytosis. Inside the endosomes of immune cells the RNA can bind to TLR7 (ssRNA), TLR8 (ssRNA), or TLR3 (dsRNA), thereby triggering innate immune pathways. When RNA escapes from the endosomes into the cytoplasm of immune and non-immune cells, it can bind to RNA helicases (e.g., in the RIG-I-like receptor family, i.e., RLRs) such as RIG-I (RLR-1), MDA5 (RLR-2), and/or LGP2 (RLR-3), also triggering innate immune pathways. The RNA can also be translated in the immune and/or non-immune cells, leading to expression of the immunogen, and ultimately to presentation of the expressed immunogen via the MHC system. The cells can also secrete type I interferons and/or pro-inflammatory cytokines to provide a local adjuvant effect.

The RNA can be delivered as naked RNA (e.g., merely as an aqueous solution of RNA), but to enhance both entry to immune and non-immune cells and also subsequent intercellular effects, and also to reduce the amount of RNA required for a good immunogenic effect, the RNA is preferably administered in combination with a delivery system, such as a particulate or emulsion delivery system. Three useful delivery systems of interest are: (i) liposomes, (ii) non-toxic and biodegradable polymer microparticles, (iii) cationic submicron oil-in-water emulsions. Liposomes are a preferred delivery system.

According to a first aspect of the invention, RNA encoding an immunogen is delivered to a large mammal at a dose of between 2 μg and 100 μg. For instance, the dose can be between 5 μg and 75 μg, between 6 μg and 50 g, between 7 μg and 25 μg, between 8 μg and 20 μg, or between 9 μg and 15 μg. Specific doses can be 5 μg, 6 μg, 7 μg, 8 μg, 9 μg, 10 μg, 11 μg, 12 μg, 13 μg, 14 μg, 15 μg, 20 μg, 25 μg, 30 μg, 35 μg, 40 μg, 45 μg, 50 μg, 60 μg, 70 μg, 80 μg, 90 μg, or 100 μg. A human dose may be 5-10 μg.

According to a second aspect of the invention, RNA encoding an immunogen is delivered to a large mammal at a dose of between 0.1 μg RNA per kg of body weight to 1.5 μg RNA per kg of body weight. For instance, the dose can be between 0.2 μg/kg to 1.2 μg/kg, between 0.3 μg/kg to 1.1 μg/kg, between 0.4 μg/kg to 1.0 μg/kg, between 0.5 μg/kg to 1.0 μg/kg, or between 0.5 μg/kg to 1.5 μg/kg.

Specific doses can be 0.1 μg/kg, 0.15 μg/kg, 0.2 μg/kg, 0.25 μg/kg, 0.3 μg/kg, 0.4 μg/kg, 0.5 μg/kg, 1 μg/kg, or 1.2 μg/kg.

Liposomes

Various amphiphilic lipids can form bilayers in an aqueous environment to encapsulate a RNA-containing aqueous core as a liposome. These lipids can have an anionic, cationic or zwitterionic hydrophilic head group. Formation of liposomes from anionic phospholipids dates back to the 1960s, and cationic liposome-forming lipids have been studied since the 1990s. Some phospholipids are anionic whereas other are zwitterionic and others are cationic. Suitable classes of phospholipid include, but are not limited to, phosphatidylethanolamines, phosphatidylcholines, phosphatidylserines, and phosphatidyl-glycerols, and some useful phospholipids are listed in Table 1. Useful cationic lipids include, but are not limited to, dioleoyl trimethylammonium propane (DOTAP), 1,2-distearyloxy-N,N-dimethyl-3-aminopropane (DSDMA), 1,2-dioleyloxy-N,N-dimethy1-3-aminopropane (DODMA), 1,2-dilinoleyloxy-N,N-dimethyl-3-aminopropane (DLinDMA), 1,2-dilinolenyloxy-N,N-dimethyl-3-aminopropane (DLenDMA). Zwitterionic lipids include, but are not limited to, acyl zwitterionic lipids and ether zwitterionic lipids. Examples of useful zwitterionic lipids are DPPC, DOPC, and dodecylphosphocholine. The lipids can be saturated or unsaturated. The use of at least one unsaturated lipid for preparing liposomes is preferred. If an unsaturated lipid has two tails, both tails can be unsaturated, or it can have one saturated tail and one unsaturated tail.

Liposomes can be formed from a single lipid or from a mixture of lipids. A mixture may comprise: (i) a mixture of anionic lipids, (ii) a mixture of cationic lipids, (iii) a mixture of zwitterionic lipids, (iv) a mixture of anionic lipids and cationic lipids, (v) a mixture of anionic lipids and zwitterionic lipids, (vi) a mixture of zwitterionic lipids and cationic lipids, or (vii) a mixture of anionic lipids, cationic lipids, and zwitterionic lipids. Similarly, a mixture may comprise both saturated and unsaturated lipids. For example, a mixture may comprise DSPC (zwitterionic, saturated), DlinDMA (cationic, unsaturated), and/or DMG (anionic, saturated). Where a mixture of lipids is used, not all of the component lipids in the mixture need to be amphiphilic; e.g., one or more amphiphilic lipids can be mixed with cholesterol.

The hydrophilic portion of a lipid can be PEGylated (i.e., modified by covalent attachment of a polyethylene glycol). This modification can increase stability and prevent non-specific adsorption of the liposomes. For instance, lipids can be conjugated to PEG using techniques such as those disclosed in references 6 and 7. Various lengths of PEG can be used, e.g., between 0.5-8 kDa.

A mixture of DSPC, DlinDMA, PEG-DMG, and cholesterol is used in the examples.

Liposomes are usually divided into three groups: multilamellar vesicles (MLV); small unilamellar vesicles (SUV); and large unilamellar vesicles (LUV). MLVs have multiple bilayers in each vesicle, forming several separate aqueous compartments. SUVs and LUVs have a single bilayer encapsulating an aqueous core; SUVs typically have a diameter ≤50 nm, and LUVs have a diameter >50 nm. Liposomes useful with and of the invention are ideally LUVs with a diameter in the range of 50-220 nm. For a composition comprising a population of LUVs with different diameters: (i) at least 80% by number should have diameters in the range of 20-220 nm, (ii) the average diameter (Zav, by intensity) of the population is ideally in the range of 40-200 nm, and/or (iii) the diameters should have a polydispersity index <0.2. The liposome/RNA complexes of reference 1 are expected to have a diameter in the range of 600-800 nm and to have a high polydispersity.

Techniques for preparing suitable liposomes are well known in the art, e.g., see references 8 to 10. One useful method is described in reference 11 and involves mixing (i) an ethanolic solution of the lipids, (ii) an aqueous solution of the nucleic acid, and (iii) buffer, followed by mixing, equilibration, dilution, and purification. Preferred liposomes of the invention are obtainable by this mixing process.

RNA is preferably encapsulated within the liposomes, and so the liposome forms an outer layer around an aqueous RNA-containing core. This encapsulation has been found to protect RNA from RNase digestion. The liposomes can include some external RNA (e.g., on the surface of the liposomes), but at least half of the RNA (and ideally all of it) is encapsulated.

Polymeric Microparticles

Various polymers can form microparticles to encapsulate or adsorb RNA. The use of a substantially non-toxic polymer means that a recipient can safely receive the particles, and the use of a biodegradable polymer means that the particles can be metabolized after delivery to avoid long-term persistence. Useful polymers are also sterilizable, to assist in preparing pharmaceutical grade formulations.

Suitable non-toxic and biodegradable polymers include, but are not limited to, poly(α-hydroxy acids), polyhydroxy butyric acids, polylactones (including polycaprolactones), polydioxanones, polyvalerolactone, polyorthoesters, polyanhydrides, polycyanoacrylates, tyrosine-derived polycarbonates, polyvinyl-pyrrolidinones or polyester-amides, and combinations thereof.

In some embodiments, the microparticles are formed from poly(α-hydroxy acids), such as a poly(lactides) (“PLA”), copolymers of lactide and glycolide such as a poly(D,L-lactide-co-glycolide) (“PLG”), and copolymers of D,L-lactide and caprolactone. Useful PLG polymers include those having a lactide/glycolide molar ratio ranging, for example, from 20:80 to 80:20, e.g., 25:75, 40:60, 45:55, 50:50, 55:45, 60:40, 75:25. Useful PLG polymers include those having a molecular weight between, for example, 5,000-200,000 Da, e.g., between 10,000-100,000, 20,000-70,000, 30,000-40,000, 40,000-50,000 Da.

The microparticles ideally have a diameter in the range of 0.02 μm to 8 μm. For a composition comprising a population of microparticles with different diameters at least 80% by number should have diameters in the range of 0.03-7 μm.

Techniques for preparing suitable microparticles are well known in the art; e.g., see references 10, 12 (in particular chapter 7), and 13. To facilitate adsorption of RNA, a microparticle may include a cationic surfactant and/or lipid, e.g., as disclosed in references 14 & 15. An alternative way of making polymeric microparticles is by molding and curing, e.g., as disclosed in reference 16.

Microparticles of the invention can have a zeta potential of between 40-100 mV.

One advantage of microparticles over liposomes is that they are readily lyophilized for stable storage.

RNA can be adsorbed to the microparticles, and adsorption is facilitated by including cationic materials (e.g., cationic lipids) in the microparticle.

Oil-In-Water Cationic Emulsions

Oil-in-water emulsions are known for adjuvanting influenza vaccines, e.g., the MF59™ adjuvant in the FLUAD™ product, and the AS03 adjuvant in the PREPANDRIX™ product. RNA delivery according to the present invention can utilize an oil-in-water emulsion, provided that the emulsion includes one or more cationic molecules. For instance, a cationic lipid can be included in the emulsion to provide a positive droplet surface to which negatively-charged RNA can attach.

The emulsion comprises one or more oils. Suitable oil(s) include those from, for example, an animal (such as fish) or a vegetable source. The oil is ideally biodegradable (metabolizable) and biocompatible. Sources for vegetable oils include nuts, seeds, and grains. Peanut oil, soybean oil, coconut oil, and olive oil, the most commonly available, exemplify the nut oils. Jojoba oil can be used, e.g., obtained from the jojoba bean. Seed oils include safflower oil, cottonseed oil, sunflower seed oil, sesame seed oil, and the like. In the grain group, corn oil is the most readily available, but the oil of other cereal grains such as wheat, oats, rye, rice, teff, triticale, and the like may also be used. 6-10 carbon fatty acid esters of glycerol and 1,2-propanediol, while not occurring naturally in seed oils, may be prepared by hydrolysis, separation and esterification of the appropriate materials starting from the nut and seed oils. Fats and oils from mammalian milk are metabolizable and so may be used. The procedures for separation, purification, saponification, and other means necessary for obtaining pure oils from animal sources are well known in the art.

Most fish contain metabolizable oils which may be readily recovered. For example, cod liver oil, shark liver oils, and whale oil such as spermaceti exemplify several of the fish oils which may be used herein.

A number of branched chain oils are synthesized biochemically in 5-carbon isoprene units and are generally referred to as terpenoids. Preferred emulsions comprise squalene, a shark liver oil which is a branched, unsaturated terpenoid(C₃₀H₅₀; [(CH₃)₂C[═CHCH₂CH₂C(CH₃)]₂═CHCH₂-]₂; 2,6,10,15,19,23-hexamethyl-2,6,10,14,18,22-tetracosahexaene; CAS RN 7683-64-9). Squalane, the saturated analog to squalene, can also be used. Fish oils, including squalene and squalane, are readily available from commercial sources or may be obtained by methods known in the art.

Other useful oils are the tocopherols, particularly in combination with squalene. Where the oil phase of an emulsion includes a tocopherol, any of the α-, β-, γ-, δ-, ε-, or ξ-tocopherols can be used, but α-tocopherols are preferred. D-α-tocopherol and DL-α-tocopherol can both be used. A preferred α-tocopherol is DL-α-tocopherol. An oil combination comprising squalene and a tocopherol (e.g., DL-α-tocopherol) can be used.

The oil in the emulsion may comprise a combination of oils, e.g., squalene and at least one further oil.

The aqueous component of the emulsion can be plain water (e.g., w.f.i.) or can include further components, e.g., solutes. For instance, it may include salts to form a buffer, e.g., citrate or phosphate salts, such as sodium salts. Typical buffers include: a phosphate buffer; a Tris buffer; a borate buffer; a succinate buffer; a histidine buffer; or a citrate buffer. A buffered aqueous phase is preferred, and buffers will typically be included in the 5-20 mM range.

The emulsion also includes a cationic lipid. Preferably this lipid is a surfactant so that it can facilitate formation and stabilization of the emulsion. Useful cationic lipids generally contain a nitrogen atom that is positively charged under physiological conditions, e.g., as a tertiary or quaternary amine. This nitrogen can be in the hydrophilic head group of an amphiphilic surfactant. Useful cationic lipids include, but are not limited to: 1,2-dioleoyloxy-3-(trimethylammonio)propane (DOTAP), 3′[N-(N′,N′-Dimethylaminoethane)-carbamoyl]Cholesterol (DC Cholesterol), dimethyldioctadecyl-ammonium (DDA, e.g., the bromide), 1,2-Dimyristoyl-3-Trimethyl-AmmoniumPropane (DMTAP), dipalmitoyl(C16:0)trimethyl ammonium propane (DPTAP), distearoyltrimethylammonium propane (DSTAP). Other useful cationic lipids are: benzalkonium chloride (BAK), benzethonium chloride, cetramide (which contains tetradecyltrimethylammonium bromide and possibly small amounts of dedecyltrimethylammonium bromide and hexadecyltrimethyl ammonium bromide), cetylpyridinium chloride (CPC), cetyl trimethylammonium chloride (CTAC), N,N′,N′-polyoxyethylene (10)-N-tallow-1,3-diaminopropane, dodecyltrimethylammonium bromide, hexadecyltrimethyl-ammonium bromide, mixed alkyl-trimethyl-ammonium bromide, benzyldimethyldodecylammonium chloride, benzyldimethylhexadecyl-ammonium chloride, benzyltrimethylammonium methoxide, cetyldimethylethylammonium bromide, dimethyldioctadecyl ammonium bromide (DDAB), methylbenzethonium chloride, decamethonium chloride, methyl mixed trialkyl ammonium chloride, methyl trioctylammonium chloride), N,N-dimethyl-N-[2 (2-methyl-4-(1,1,3,3tetramethylbutyl)-phenoxy]-ethoxy)ethyl]-benzenemetha-naminium chloride (DEBDA), dialkyldimetylammonium salts, [1-(2,3-dioleyloxy)-propyl]-N,N,N,trimethylammonium chloride, 1,2-diacy1-3-(trimethylammonio) propane (acyl group=dimyristoyl, dipalmitoyl, distearoyl, dioleoyl), 1,2-diacyl-3 (dimethylammonio)propane (acyl group=dimyristoyl, dipalmitoyl, distearoyl, dioleoyl), 1,2-dioleoyl-3-(4′-trimethyl-ammonio)butanoyl-sn-glycerol, 1,2-dioleoyl 3-succinyl-sn-glycerol choline ester, cholesteryl (4′-trimethylammonio) butanoate, N-alkyl pyridinium salts (e.g., cetylpyridinium bromide and cetylpyridinium chloride), N-alkylpiperidinium salts, dicationic bolaform electrolytes (C₁₂Me₆; C₁₂Bu₆), dialkylglycetylphosphorylcholine, lysolecithin, L-α dioleoyl-phosphatidylethanolamine, cholesterol hemisuccinate choline ester, lipopolyamines, including but not limited to dioctadecylamidoglycylspermine (DOGS), dipalmitoyl phosphatidylethanol-amidospermine (DPPES), lipopoly-L (or D)-lysine (LPLL, LPDL), poly (L (or D)-lysine conjugated to N-glutarylphosphatidylethanolamine, didodecyl glutamate ester with pendant amino group (C₁₂GluPhC_(n),N⁺), ditetradecyl glutamate ester with pendant amino group (C₁₂GluPhC_(n),N⁺), cationic derivatives of cholesterol, including but not limited to cholesteryl-3 β-oxysuccinamidoethylenetrimethylammonium salt, cholesteryl-3 β-oxysuccinamidoethylene-dimethylamine, cholesteryl-3 β-carboxyamidoethylenetrimethylammonium salt, and cholesteryl-3 β-carboxyamidoethylenedimethylamine. Other useful cationic lipids are described in refs. 17 & 18.

The cationic lipid is preferably biodegradable (metabolizable) and biocompatible.

In addition to the oil and cationic lipid, an emulsion can include a non-ionic surfactant and/or a zwitterionic surfactant. Such surfactants include, but are not limited to: the polyoxyethylene sorbitan esters surfactants (commonly referred to as the Tweens), especially polysorbate 20 and polysorbate 80; copolymers of ethylene oxide (EO), propylene oxide (PO), and/or butylene oxide (BO), sold under the DOWFAX™ tradename, such as linear EO/PO block copolymers; octoxynols, which can vary in the number of repeating ethoxy (oxy-1,2-ethanediyl) groups, with octoxynol-9 (Triton X-100, or t-octylphenoxypolyethoxyethanol) being of particular interest; (octylphenoxy)polyethoxyethanol (IGEPAL CA-630/NP-40); phospholipids such as phosphatidylcholine (lecithin); polyoxyethylene fatty ethers derived from lauryl, cetyl, stearyl, and oleyl alcohols (known as Brij surfactants), such as triethyleneglycol monolauryl ether (Brij 30); polyoxyethylene-9-lauryl ether; and sorbitan esters (commonly known as the Spans), such as sorbitan trioleate (Span 85) and sorbitan monolaurate. Preferred surfactants for including in the emulsion are polysorbate 80 (Tween 80; polyoxyethylene sorbitan monooleate), Span 85 (sorbitan trioleate), lecithin, and Triton X-100.

Mixtures of these surfactants can be included in the emulsion, e.g., Tween 80/Span 85 mixtures, or Tween 80/Triton-X100 mixtures. A combination of a polyoxyethylene sorbitan ester such as polyoxyethylene sorbitan monooleate (Tween 80) and an octoxynol such as t-octylphenoxy-polyethoxyethanol (Triton X-100) is also suitable. Another useful combination comprises laureth 9 plus a polyoxyethylene sorbitan ester and/or an octoxynol. Useful mixtures can comprise a surfactant with a HLB value in the range of 10-20 (e.g., polysorbate 80, with a HLB of 15.0) and a surfactant with a HLB value in the range of 1-10 (e.g., sorbitan trioleate, with a HLB of 1.8).

Preferred amounts of oil (% by volume) in the final emulsion are between 2-20%, e.g., 5-15%, 6-14%, 7-13%, 8-12%. A squalene content of about 4-6% or about 9-11% is particularly useful.

Preferred amounts of surfactants (% by weight) in the final emulsion are between 0.001% and 8%. For example: polyoxyethylene sorbitan esters (such as polysorbate 80) 0.2 to 4%, in particular between 0.4-0.6%, between 0.45-0.55%, about 0.5% or between 1.5-2%, between 1.8-2.2%, between 1.9-2.1%, about 2%, or 0.85-0.95%, or about 1%; sorbitan esters (such as sorbitan trioleate) 0.02 to 2%, in particular about 0.5% or about 1%; octyl- or nonylphenoxy polyoxyethanols (such as Triton X-100) 0.001 to 0.1%, in particular 0.005 to 0.02%; polyoxyethylene ethers (such as laureth 9) 0.1 to 8%, preferably 0.1 to 10% and in particular 0.1 to 1% or about 0.5%.

The absolute amounts of oil and surfactant, and their ratio, can be varied within wide limits while still forming an emulsion. A skilled person can easily vary the relative proportions of the components to obtain a desired emulsion, but a weight ratio of between 4:1 and 5:1 for oil and surfactant is typical (excess oil).

An important parameter for ensuring immunostimulatory activity of an emulsion, particularly in large animals, is the oil droplet size (diameter). The most effective emulsions have a droplet size in the submicron range. Suitably the droplet sizes will be in the range 50-750 nm. Most usefully the average droplet size is less than 250 nm, e.g., less than 200 nm, less than 150 nm. The average droplet size is usefully in the range of 80-180 nm. Ideally, at least 80% (by number) of the emulsion's oil droplets are less than 250 nm in diameter, and preferably at least 90%. Apparatuses for determining the average droplet size in an emulsion, and the size distribution, are commercially available. These typically use the techniques of dynamic light scattering and/or single-particle optical sensing, e.g., the ACCUSIZER™ and NICOMP™ series of instruments available from Particle Sizing Systems (Santa Barbara, USA), or the ZETASIZER™ instruments from Malvern Instruments (UK), or the Particle Size Distribution Analyzer instruments from Horiba (Kyoto, Japan).

Ideally, the distribution of droplet sizes (by number) has only one maximum, i.e., there is a single population of droplets distributed around an average (mode), rather than having two maxima. Preferred emulsions have a polydispersity of <0.4, e.g., 0.3, 0.2, or less.

Suitable emulsions with submicron droplets and a narrow size distribution can be obtained by the use of microfluidization. This technique reduces average oil droplet size by propelling streams of input components through geometrically fixed channels at high pressure and high velocity. These streams contact channel walls, chamber walls, and each other. The results shear, impact, and cavitation forces cause a reduction in droplet size. Repeated steps of microfluidization can be performed until an emulsion with a desired droplet size average and distribution are achieved.

As an alternative to microfluidization, thermal methods can be used to cause phase inversion, as disclosed in reference 19. These methods can also provide a submicron emulsion with a tight particle size distribution.

Preferred emulsions can be filter sterilized, i.e., their droplets can pass through a 220 nm filter. As well as providing a sterilization, this procedure also removes any large droplets in the emulsion.

In certain embodiments, the cationic lipid in the emulsion is DOTAP. The cationic oil-in-water emulsion may comprise from about 0.5 mg/ml to about 25 mg/ml DOTAP. For example, the cationic oil-in-water emulsion may comprise DOTAP at from about 0.5 mg/ml to about 25 mg/ml, from about 0.6 mg/ml to about 25 mg/ml, from about 0.7 mg/ml to about 25 mg/ml, from about 0.8 mg/ml to about 25 mg/ml, from about 0.9 mg/ml to about 25 mg/ml, from about 1.0 mg/ml to about 25 mg/ml, from about 1.1 mg/ml to about 25 mg/ml, from about 1.2 mg/ml to about 25 mg/ml, from about 1.3 mg/ml to about 25 mg/ml, from about 1.4 mg/ml to about 25 mg/ml, from about 1.5 mg/ml to about 25 mg/ml, from about 1.6 mg/ml to about 25 mg/ml, from about 1.7 mg/ml to about 25 mg/ml, from about 0.5 mg/ml to about 24 mg/ml, from about 0.5 mg/ml to about 22 mg/ml, from about 0.5 mg/ml to about 20 mg/ml, from about 0.5 mg/ml to about 18 mg/ml, from about 0.5 mg/ml to about 15 mg/ml, from about 0.5 mg/ml to about 12 mg/ml, from about 0.5 mg/ml to about 10 mg/ml, from about 0.5 mg/ml to about 5 mg/ml, from about 0.5 mg/ml to about 2 mg/ml, from about 0.5 mg/ml to about 1.9 mg/ml, from about 0.5 mg/ml to about 1.8 mg/ml, from about 0.5 mg/ml to about 1.7 mg/ml, from about 0.5 mg/ml to about 1.6 mg/ml, from about 0.6 mg/ml to about 1.6 mg/ml, from about 0.7 mg/ml to about 1.6 mg/ml, from about 0.8 mg/ml to about 1.6 mg/ml, about 0.5 mg/ml, about 0.6 mg/ml, about 0.7 mg/ml, about 0.8 mg/ml, about 0.9 mg/ml, about 1.0 mg/ml, about 1.1 mg/ml, about 1.2 mg/ml, about 1.3 mg/ml, about 1.4 mg/ml, about 1.5 mg/ml, about 1.6 mg/ml, about 12 mg/ml, about 18 mg/ml, about 20 mg/ml, about 21.8 mg/ml, about 24 mg/ml, etc. In an exemplary embodiment, the cationic oil-in-water emulsion comprises from about 0.8 mg/ml to about 1.6 mg/ml DOTAP, such as 0.8 mg/ml, 1.2 mg/ml, 1.4 mg/ml, or 1.6 mg/ml.

In certain embodiments, the cationic lipid is DC Cholesterol. The cationic oil-in-water emulsion may comprise DC Cholesterol at from about 0.1 mg/ml to about 5 mg/ml DC Cholesterol. For example, the cationic oil-in-water emulsion may comprise DC Cholesterol from about 0.1 mg/ml to about 5 mg/ml, from about 0.2 mg/ml to about 5 mg/ml, from about 0.3 mg/ml to about 5 mg/ml, from about 0.4 mg/ml to about 5 mg/ml, from about 0.5 mg/ml to about 5 mg/ml, from about 0.62 mg/ml to about 5 mg/ml, from about 1 mg/ml to about 5 mg/ml, from about 1.5 mg/ml to about 5 mg/ml, from about 2 mg/ml to about 5 mg/ml, from about 2.46 mg/ml to about 5 mg/ml, from about 3 mg/ml to about 5 mg/ml, from about 3.5 mg/ml to about 5 mg/ml, from about 4 mg/ml to about 5 mg/ml, from about 4.5 mg/ml to about 5 mg/ml, from about 0.1 mg/ml to about 4.92 mg/ml, from about 0.1 mg/ml to about 4.5 mg/ml, from about 0.1 mg/ml to about 4 mg/ml, from about 0.1 mg/ml to about 3.5 mg/ml, from about 0.1 mg/ml to about 3 mg/ml, from about 0.1 mg/ml to about 2.46 mg/ml, from about 0.1 mg/ml to about 2 mg/ml, from about 0.1 mg/ml to about 1.5 mg/ml, from about 0.1 mg/ml to about 1 mg/ml, from about 0.1 mg/ml to about 0.62 mg/ml, about 0.15 mg/ml, about 0.3 mg/ml, about 0.6 mg/ml, about 0.62 mg/ml, about 0.9 mg/ml, about 1.2 mg/ml, about 2.46 mg/ml, about 4.92 mg/ml, etc. In an exemplary embodiment, the cationic oil-in-water emulsion comprises from about 0.62 mg/ml to about 4.92 mg/ml DC Cholesterol, such as 2.46 mg/ml.

In certain embodiments, the cationic lipid is DDA. The cationic oil-in-water emulsion may comprise from about 0.1 mg/ml to about 5 mg/ml DDA. For example, the cationic oil-in-water emulsion may comprise DDA at from about 0.1 mg/ml to about 5 mg/ml, from about 0.1 mg/ml to about 4.5 mg/ml, from about 0.1 mg/ml to about 4 mg/ml, from about 0.1 mg/ml to about 3.5 mg/ml, from about 0.1 mg/ml to about 3 mg/ml, from about 0.1 mg/ml to about 2.5 mg/ml, from about 0.1 mg/ml to about 2 mg/ml, from about 0.1 mg/ml to about 1.5 mg/ml, from about 0.1 mg/ml to about 1.45 mg/ml, from about 0.2 mg/ml to about 5 mg/ml, from about 0.3 mg/ml to about 5 mg/ml, from about 0.4 mg/ml to about 5 mg/ml, from about 0.5 mg/ml to about 5 mg/ml, from about 0.6 mg/ml to about 5 mg/ml, from about 0.73 mg/ml to about 5 mg/ml, from about 0.8 mg/ml to about 5 mg/ml, from about 0.9 mg/ml to about 5 mg/ml, from about 1.0 mg/ml to about 5 mg/ml, from about 1.2 mg/ml to about 5 mg/ml, from about 1.45 mg/ml to about 5 mg/ml, from about 2 mg/ml to about 5 mg/ml, from about 2.5 mg/ml to about 5 mg/ml, from about 3 mg/ml to about 5 mg/ml, from about 3.5 mg/ml to about 5 mg/ml, from about 4 mg/ml to about 5 mg/ml, from about 4.5 mg/ml to about 5 mg/ml, about 1.2 mg/ml, about 1.45 mg/ml, etc. Alternatively, the cationic oil-in-water emulsion may comprise DDA at about 20 mg/ml, about 21 mg/ml, about 21.5 mg/ml, about 21.6 mg/ml, about 25 mg/ml. In an exemplary embodiment, the cationic oil-in-water emulsion comprises from about 0.73 mg/ml to about 1.45 mg/ml DDA, such as 1.45 mg/ml.

Certain preferred compositions of the invention for administration to a patient comprise squalene, span 85, polysorbate 80, and DOTAP. For instance: squalene may be present at 5-15 mg/ml; span 85 may be present at 0.5-2 mg/ml; polysorbate 80 may be present at 0.5-2 mg/ml; and DOTAP may be present at 0.1-10 mg/ml. The emulsion can include the same amount (by volume) of span 85 and polysorbate 80.

The emulsion can include more squalene than surfactant. The emulsion can include more squalene than DOTAP.

The RNA

The invention involves in vivo delivery of RNA which encodes an immunogen. The RNA can trigger innate immunity pathways and is also translated, leading to expression of the immunogen.

The RNA is +-stranded, and so it can be translated without needing any intervening replication steps such as reverse transcription.

Preferred+-stranded RNAs are self-replicating. A self-replicating RNA molecule (replicon) can, when delivered to a mammalian cell even without any proteins, lead to the production of multiple daughter RNAs by transcription from itself (via an antisense copy which it generates from itself).

A self-replicating RNA molecule is thus typically a +-strand molecule which can be directly translated after delivery to a cell, and this translation provides a RNA-dependent RNA polymerase which then produces both antisense and sense transcripts from the delivered RNA. Thus, the delivered RNA leads to the production of multiple daughter RNAs. These daughter RNAs, as well as collinear subgenomic transcripts, may be translated themselves to provide in situ expression of an encoded immunogen, or may be transcribed to provide further transcripts with the same sense as the delivered RNA which are translated to provide in situ expression of the immunogen. The overall results of this sequence of transcriptions is a huge amplification in the number of the introduced replicon RNAs and so the encoded immunogen becomes a major polypeptide product of the cells.

One suitable system for achieving self-replication is to use an alphavirus-based RNA replicon. These +-stranded replicons are translated after delivery to a cell to give of a replicase (or replicase-transcriptase). The replicase is translated as apolyprotein which auto-cleaves to provide a replication complex which creates genomic—strand copies of the +-strand delivered RNA. These—strand transcripts can themselves be transcribed to give further copies of the +-stranded parent RNA and also to give a subgenomic transcript which encodes the immunogen. Translation of the subgenomic transcript thus leads to in situ expression of the immunogen by the infected cell. Suitable alphavirus replicons can use a replicase from a Sindbis virus, a Semliki Forest virus, an eastern equine encephalitis virus, a Venezuelan equine encephalitis virus (VEEV), etc. Mutant or wild-type viruses sequences can be used, e.g., the attenuated TC83 mutant of VEEV has been used in replicons (see reference [20]).

A preferred self-replicating RNA molecule thus encodes (i) a RNA-dependent RNA polymerase which can transcribe RNA from the self-replicating RNA molecule and (ii) an immunogen. The polymerase can be an alphavirus replicase, e.g., comprising one or more of alphavirus proteins nsP1, nsP2, nsP3 and nsP4.

Whereas natural alphavirus genomes encode structural virion proteins in addition to the non-structural replicase polyprotein, it is preferred that a self-replicating RNA molecule of the invention does not encode alphavirus structural proteins. Thus, a preferred self-replicating RNA can lead to the production of genomic RNA copies of itself in a cell, but not to the production of RNA-containing virions. The inability to produce these virions means that, unlike a wild-type alphavirus, the self-replicating RNA molecule cannot perpetuate itself in infectious form. The alphavirus structural proteins which are necessary for perpetuation in wild-type viruses are absent from self-replicating RNAs of the invention and their place is taken by gene(s) encoding the immunogen of interest, such that the subgenomic transcript encodes the immunogen rather than the structural alphavirus virion proteins.

Thus, a self-replicating RNA molecule useful with the invention may have two open reading frames.

The first (5′) open reading frame encodes a replicase; the second (3′) open reading frame encodes an immunogen. In some embodiments the RNA may have additional (e.g., downstream) open reading frames, e.g., to encode further immunogens (see below) or to encode accessory polypeptides.

A self-replicating RNA molecule can have a 5′ sequence which is compatible with the encoded replicase.

Self-replicating RNA molecules can have various lengths, but they are typically 5000-25000 nucleotides long, e.g., 8000-15000 nucleotides, or 9000-12000 nucleotides. Thus, the RNA is longer than seen in siRNA delivery.

A RNA molecule useful with the invention may have a 5′ cap (e.g., a 7-methylguanosine). This cap can enhance in vivo translation of the RNA.

The 5′ nucleotide of a RNA molecule useful with the invention may have a 5′ triphosphate group. In a capped RNA this may be linked to a 7-methylguanosine via a 5′-to-5′ bridge. A 5′ triphosphate can enhance RIG-I binding.

A RNA molecule may have a 3′ poly-A tail. It may also include a poly-A polymerase recognition sequence (e.g., AAUAAA) near its 3′ end.

A RNA molecule useful with the invention will typically be single-stranded. Single-stranded RNAs can generally initiate an adjuvant effect by binding to TLR7, TLR8, RNA helicases, and/or PKR. RNA delivered in double-stranded form (dsRNA) can bind to TLR3, and this receptor can also be triggered by dsRNA which is formed either during replication of a single-stranded RNA or within the secondary structure of a single-stranded RNA.

A RNA molecule useful with the invention can conveniently be prepared by in vitro transcription (IVT). IVT can use a (cDNA) template created and propagated in plasmid form in bacteria or created synthetically (for example, by gene synthesis and/or polymerase chain-reaction (PCR) engineering methods). For instance, a DNA-dependent RNA polymerase (such as the bacteriophage T7, T3, or SP6 RNA polymerases) can be used to transcribe the RNA from a DNA template.

Appropriate capping and poly-A addition reactions can be used as required (although the replicon's poly-A is usually encoded within the DNA template). These RNA polymerases can have stringent requirements for the transcribed 5′ nucleotide(s) and in some embodiments these requirements must be matched with the requirements of the encoded replicase, to ensure that the IVT-transcribed RNA can function efficiently as a substrate for its self-encoded replicase.

As discussed in reference 21, the self-replicating RNA can include (in addition to any 5′ cap structure) one or more nucleotides having a modified nucleobase. Thus, the RNA can comprise m5C (5-methylcytidine), m5U (5-methyluridine), m6A (N6-methyladenosine), s2U (2-thiouridine), Um (2′-O-methyluridine), m1A (1-methyladenosine); m2A (2-methyladenosine); Am (2′-O-methyladenosine); ms2m6A (2-methylthio-N6-methyladenosine); i6A (N6-isopentenyladenosine); ms2i6A (2-methylthio-N6-isopentenyladenosine); io6A (N6-(cis-hydroxyisopentenyl)adenosine); ms2io6A (2-methylthio-N6-(cis-hydroxyisopentenyl) adenosine); g6A (N6-glycinylcarbamoyladenosine); t6A (N6-threonyl carbamoyladenosine); ms2t6A (2-methylthio-N6-threonyl carbamoyladenosine); m6t6A (N6-methyl-N6-threonylcarbamoyladenosine); hn6A (N6-hydroxynorvalylcarbamoyl adenosine); ms2hn6A (2-methylthio-N6-hydroxynorvalyl carbamoyladenosine); Ar(p) (2′-O-ribosyladenosine (phosphate)); I (inosine); m1I (1-methylinosine); m′Im (1,2′-O-dimethylinosine); m3C (3-methylcytidine); Cm (2T-O-methylcytidine); s2C (2-thiocytidine); ac4C (N4-acetylcytidine); f5C (5-fonnylcytidine); m5Cm (5,2-O-dimethylcytidine); ac4Cm (N4-acetyl2TOmethylcytidine); k2C (lysidine); m1G (1-methylguanosine); m2G (N2-methylguanosine); m7G (7-methylguanosine); Gm (2′-O-methylguanosine); m22G (N2,N2-dimethylguanosine); m2Gm (N2,2′-O-dimethylguanosine); m22Gm (N2,N2,2′-O-trimethylguanosine); Gr(p) (2′-O-ribosylguanosine (phosphate)); yW (wybutosine); o2yW (peroxywybutosine); OHyW (hydroxywybutosine); OHyW* (undermodified hydroxywybutosine); imG (wyosine); mimG (methylguanosine); Q (queuosine); oQ (epoxyqueuosine); galQ (galtactosyl-queuosine); manQ (mannosyl-queuosine); preQo (7-cyano-7-deazaguanosine); preQi (7-aminomethyl-7-deazaguanosine); G* (archaeosine); D (dihydrouridine); m5Um (5,2′-O-dimethyluridine); s4U (4-thiouridine); m5s2U (5-methyl-2-thiouridine); s2Um (2-thio-2′-O-methyluridine); acp3U (3-(3-amino-3-carboxypropyl)uridine); ho5U (5-hydroxyuridine); mo5U (5-methoxyuridine); cmo5U (uridine 5-oxyacetic acid); mcmo5U (uridine 5-oxyacetic acid methyl ester); chm5U (5-(carboxyhydroxymethyl)uridine)); mchm5U (5-(carboxyhydroxymethyl)uridine methyl ester); mcm5U (5-methoxycarbonyl methyluridine); mcm5Um (S-methoxycarbonylmethyl-2-O-methyluridine); mcm5s2U (5-methoxycarbonylmethyl-2-thiouridine); nm5s2U (5-aminomethyl-2-thiouridine); mnm5U (5-methylaminomethyluridine); mnm5s2U (5-methylaminomethyl-2-thiouridine); mnm5se2U (5-methylaminomethyl-2-selenouridine); ncm5U (5-carbamoylmethyluridine); ncm5Um (5-carbamoylmethyl-2′-O-methyluridine); cmnm5U (5-carboxymethylaminomethyluridine); cnmm5Um (5-carboxymethylaminomethyl-2-L-O-methyluridine); cmnm5s2U (5-carboxymethylaminomethyl-2-thiouridine); m62A (N6,N6-dimethyladenosine); Tm (2′-O-methylinosine); m4C (N4-methylcytidine); m4Cm (N4,2-O-dimethylcytidine); hm5C (5-hydroxymethylcytidine); m3U (3-methyluridine); cm5U (5-carboxymethyluridine); m6Am (N6,T-O-dimethyladenosine); m62Am (N6,N6,0-2-trimethyladenosine); m2′7G (N2,7-dimethylguanosine); m2′2′7G (N2,N2,7-trimethylguanosine); m3Um (3,2T-O-dimethyluridine); m5D (5-methyldihydrouridine); f5Cm (5-formyl-2′-O-methylcytidine); m1Gm (1,2′-O-dimethylguanosine); m′Am (1,2-O-dimethyl adenosine); irinomethyluridine; tm5s2U (S-taurinomethyl-2-thiouridine)); imG-14 (4-demethyl guanosine); imG2 (isoguanosine); or ac6A (N6-acetyladenosine), hypoxanthine, inosine, 8-oxo-adenine, 7-substituted derivatives thereof, dihydrouracil, pseudouracil, 2-thiouracil, 4-thiouracil, 5-aminouracil, 5-(C1-C6)-alkyluracil, 5-methyluracil, 5-(C2-C6)-alkenyluracil, 5-(C2-C6)-alkynyluracil, 5-(hydroxymethyl)uracil, 5-chlorouracil, 5-fluorouracil, 5-bromouracil, 5-hydroxycytosine, 5-(C1-C6)-alkylcytosine, 5-methylcytosine, 5-(C2-C6)-alkenylcytosine, 5-(C2-C6)-alkynylcytosine, 5-chlorocytosine, 5-fluorocytosine, 5-bromocytosine, N2-dimethylguanine, 7-deazaguanine, 8-azaguanine, 7-deaza-7-substituted guanine, 7-deaza-7-(C2-C6)alkynylguanine, 7-deaza-8-substituted guanine, 8-hydroxyguanine, 6-thioguanine, 8-oxoguanine, 2-aminopurine, 2-amino-6-chloropurine, 2,4-diaminopurine, 2,6-diaminopurine, 8-azapurine, substituted 7-deazapurine, 7-deaza-7-substituted purine, 7-deaza-8-substituted purine, or an abasic nucleotide. For instance, a self-replicating RNA can include one or more modified pyrimidine nucleobases, such as pseudouridine and/or 5-methylcytosine residues. In some embodiments, however, the RNA includes no modified nucleobases, and may include no modified nucleotides; i.e., all of the nucleotides in the RNA are standard A, C, G, and U ribonucleotides (except for any 5′ cap structure, which may include a 7-methylguanosine). In other embodiments, the RNA may include a 5′ cap comprising a 7-methylguanosine, and the first 1, 2, or 3 5′ ribonucleotides may be methylated at the 2′ position of the ribose.

A RNA used with the invention ideally includes only phosphodiester linkages between nucleosides, but in some embodiments, it can contain phosphoramidate, phosphorothioate, and/or methylphosphonate linkages.

Ideally, administered RNA includes fewer than 10 different species of RNA, e.g., 5, 4, 3, or 2 different species; most preferably, a composition includes a single RNA species; i.e., all RNA molecules in the composition (e.g., within a liposome) have the same sequence and same length.

The Immunogen

RNA molecules used with the invention encode a polypeptide immunogen. After administration of the RNA, the immunogen is translated in vivo and can elicit an immune response in the recipient. The immunogen may elicit an immune response against a bacterium, a virus, a fungus, or a parasite (or, in some embodiments, against an allergen; and in other embodiments, against a tumor antigen). The immune response may comprise an antibody response (usually including IgG) and/or a cell-mediated immune response. The polypeptide immunogen will typically elicit an immune response which recognizes the corresponding bacterial, viral, fungal, or parasite (or allergen or tumor) polypeptide, but in some embodiments the polypeptide may act as a mimotope to elicit an immune response which recognizes a bacterial, viral, fungal, or parasite saccharide. The immunogen will typically be a surface polypeptide, e.g., an adhesin, a hemagglutinin, an envelope glycoprotein, a spike glycoprotein, etc.

RNA molecules can encode a single polypeptide immunogen or multiple polypeptides. Multiple immunogens can be presented as a single polypeptide immunogen (fusion polypeptide) or as separate polypeptides. If immunogens are expressed as separate polypeptides, then one or more of these may be provided with an upstream IRES or an additional viral promoter element. Alternatively, multiple immunogens may be expressed from a polyprotein that encodes individual immunogens fused to a short autocatalytic protease (e.g., foot-and-mouth disease virus 2A protein), or as inteins.

Unlike references 1 and 22, the RNA encodes an immunogen. For the avoidance of doubt, the invention does not encompass RNA that encodes a firefly luciferase or that encodes a fusion protein of E. coli β-galactosidase or that encodes a green fluorescent protein (GFP). Also, the RNA is not total mouse thymus RNA.

In some embodiments the immunogen elicits an immune response against one of these bacteria:

-   -   Neisseria meningitidis: useful immunogens include, but are not         limited to, membrane proteins such as adhesins,         autotransporters, toxins, iron acquisition proteins, and factor         H binding protein. A combination of three useful polypeptides is         disclosed in reference 23.     -   Streptococcus pneumoniae: useful polypeptide immunogens are         disclosed in reference 24. These include, but are not limited         to, the RrgB pilus subunit, the beta-N-acetyl-hexosaminidase         precursor (spr0057), spr0096, General stress protein GSP-781         (spr2021, SP2216), serine/threonine kinase StkP (SP1732), and         pneumococcal surface adhesin PsaA.     -   Streptococcus pyogenes: useful immunogens include, but are not         limited to, the polypeptides disclosed in references 25 and 26.     -   Moraxella catarrhalis.         -   Bordetella pertussis: Useful pertussis immunogens include,             but are not limited to, pertussis toxin or toxoid (PT),             filamentous haemagglutinin (FHA), pertactin, and             agglutinogens 2 and 3.     -   Staphylococcus aureus: Useful immunogens include, but are not         limited to, the polypeptides disclosed in reference 27, such as         a hemolysin, esxA, esxB, ferrichrome-binding protein (sta006),         and/or the sta011 lipoprotein.     -   Clostridium tetani: the typical immunogen is tetanus toxoid.     -   Cornynebacterium diphtheriae: the typical immunogen is         diphtheria toxoid.     -   Haemophilus influenzae: Useful immunogens include, but are not         limited to, the polypeptides disclosed in references 28 and 29.     -   Pseudomonas aeruginosa     -   Streptococcus agalactiae: useful immunogens include, but are not         limited to, the polypeptides disclosed in reference 25.     -   Chlamydia trachomatis: Useful immunogens include, but are not         limited to, PepA, LcrE, ArtJ, DnaK, CT398, OmpH-like, L7/L12,         OmcA, AtoS, CT547, Eno, HtrA, and MurG (e.g., as disclosed in         reference 30. LcrE (see reference [31]) and HtrA (see reference         [32]) are two preferred immunogens.     -   Chlamydia pneumoniae: Useful immunogens include, but are not         limited to, the polypeptides disclosed in reference 33.     -   Helicobacter pylori: Useful immunogens include, but are not         limited to, CagA, VacA, NAP, and/or urease (see reference [34]).     -   Escherichia coli: Useful immunogens include, but are not limited         to, immunogens derived from enterotoxigenic E. coli (ETEC),         enteroaggregative E. coli (EAggEC), diffusely adhering E. coli         (DAEC), enteropathogenic E. coli (EPEC), extraintestinal         pathogenic E. coli (ExPEC), and/or enterohemorrhagic E. coli         (EHEC). ExPEC strains include uropathogenic E. coli (UPEC) and         meningitis/sepsis-associated E. coli (MNEC). Useful UPEC         polypeptide immunogens are disclosed in references 35 and 36.         Useful MNEC immunogens are disclosed in reference 37. A useful         immunogen for several E. coli types is AcfD (see reference         [38]).     -   Bacillus anthracis     -   Yersinia pestis: Useful immunogens include, but are not limited         to, those disclosed in references 39 and 40.     -   Staphylococcus epidermis     -   Clostridium perfringens or Clostridium botulinums     -   Legionella pneumophila     -   Coxiella burnetii     -   Brucella, such as B.abortus, B.canis, B.melitensis, B.neotomae,         B.ovis, B.suis, B.pinnipediae.     -   Francisella, such as F.novicida, F.philomiragia, F.tularensis.     -   Neisseria gonorrhoeae     -   Treponema pallidum     -   Haemophilus ducreyi     -   Enterococcus faecalis or Enterococcus faecium     -   Staphylococcus saprophyticus     -   Yersinia enterocolitica     -   Mycobacterium tuberculosis     -   Rickettsia     -   Listeria monocytogenes     -   Vibrio cholerae     -   Salmonella typhi     -   Borrelia burgdorferi     -   Porphyromonas gingivalis     -   Klebsiella

In some embodiments the immunogen elicits an immune response against one of these viruses:

-   -   Orthomyxovirus: Useful immunogens can be from an influenza A, B,         or C virus, such as the hemagglutinin, neuraminidase, or matrix         M2 proteins. Where the immunogen is an influenza A virus         hemagglutinin it may be from any subtype, e.g., H1, H2, H3, H4,         H5, H6, H7, H8, H9, H10, H11, H12, H13, H14, H15, or H16.     -   Paramyxoviridae viruses: Viral immunogens include, but are not         limited to, those derived from Pneumoviruses (e.g., respiratory         syncytial virus, RSV), Rubulaviruses (e.g., mumps virus),         Paramyxoviruses (e.g., parainfluenza virus), Metapneumoviruses         and Morbilliviruses (e.g., measles virus).     -   Poxviridae: Viral immunogens include, but are not limited to,         those derived from Orthopoxvirus such as Variola vera, including         but not limited to, Variola major and Variola minor.     -   Picornavirus: Viral immunogens include, but are not limited to,         those derived from Picornaviruses, such as Enteroviruses,         Rhinoviruses, Heparnavirus, Cardioviruses, and Aphthoviruses. In         one embodiment, the enterovirus is a poliovirus, e.g., a type 1,         type 2, and/or type 3 poliovirus. In another embodiment, the         enterovirus is an EV71 enterovirus. In another embodiment, the         enterovirus is a coxsackie A or B virus.     -   Bunyavirus: Viral immunogens include, but are not limited to,         those derived from an Orthobunyavirus, such as California         encephalitis virus, a Phlebovirus, such as Rift Valley Fever         virus, or a Nairovirus, such as Crimean-Congo hemorrhagicfever         virus.     -   Heparnavirus: Viral immunogens include, but are not limited to,         those derived from a Heparnavirus, such as hepatitis A virus         (HAV).     -   Filovirus: Viral immunogens include, but are not limited to,         those derived from a filovirus, such as an Ebola virus         (including a Zaire, Ivory Coast, Reston, or Sudan ebolavirus) or         a Marburg virus.     -   Togavirus: Viral immunogens include, but are not limited to,         those derived from a Togavirus, such as a Rubivirus, an         Alphavirus, or an Arterivirus. This includes rubella virus.     -   Flavivirus: Viral immunogens include, but are not limited to,         those derived from a Flavivirus, such as Tick-borne encephalitis         (TBE) virus, Dengue (types 1, 2, 3, or 4) virus, Yellow Fever         virus, Japanese encephalitis virus, Kyasanur Forest Virus, West         Nile encephalitis virus, St. Louis encephalitis virus, Russian         spring-summer encephalitis virus, Powassan encephalitis virus.     -   Pestivirus: Viral immunogens include, but are not limited to,         those derived from a Pestivirus, such as Bovine viral diarrhea         (BVDV), Classical swine fever (CSFV), or Border disease (BDV).     -   Hepadnavirus: Viral immunogens include, but are not limited to,         those derived from a Hepadnavirus, such as Hepatitis B virus. A         composition can include hepatitis B virus surface antigen         (HBsAg).     -   Other hepatitis viruses: A composition can include an immunogen         from a hepatitis C virus, delta hepatitis virus, hepatitis E         virus, or hepatitis G virus.     -   Rhabdovirus: Viral immunogens include, but are not limited to,         those derived from a Rhabdovirus, such as a Lyssavirus (e.g., a         Rabies virus) and Vesiculovirus (VSV).     -   Caliciviridae: Viral immunogens include, but are not limited to,         those derived from Calciviridae, such as Norwalk virus         (Norovirus), and Norwalk-like Viruses, such as Hawaii Virus and         Snow Mountain Virus.     -   Coronavirus: Viral immunogens include, but are not limited to,         those derived from a SARS coronavirus, avian infectious         bronchitis (IBV), Mouse hepatitis virus (MHV), and Porcine         transmissible gastroenteritis virus (TGEV). The coronavirus         immunogen may be a spike polypeptide.     -   Retrovirus: Viral immunogens include, but are not limited to,         those derived from an Oncovirus, a Lentivirus (e.g., HIV-1 or         HIV-2), or a Spumavirus.     -   Reovirus: Viral immunogens include, but are not limited to,         those derived from an Orthoreovirus, a Rotavirus, an Orbivirus,         or a Coltivirus.     -   Parvovirus: Viral immunogens include, but are not limited to,         those derived from Parvovirus B19.     -   Herpesvirus: Viral immunogens include, but are not limited to,         those derived from a human herpesvirus, such as, by way of         example only, Herpes Simplex Viruses (HSV) (e.g., HSV types 1         and 2), Varicella-zoster virus (VZV), Epstein-Barr virus (EBV),         Cytomegalovirus (CMV), Human Herpesvirus 6 (HHV6), Human         Herpesvirus 7 (HHV7), and Human Herpesvirus 8 (HHV8).     -   Papovaviruses: Viral immunogens include, but are not limited to,         those derived from Papillomaviruses and Polyomaviruses. The         (human) papillomavirus may be of serotype 1, 2, 4, 5, 6, 8, 11,         13, 16, 18, 31, 33, 35, 39, 41, 42, 47, 51, 57, 58, 63, or 65,         e.g., from one or more of serotypes 6, 11, 16, and/or 18.     -   Adenovirus: Viral immunogens include those derived from         adenovirus serotype 36 (Ad-36).

In some embodiments, the immunogen elicits an immune response against a virus which infects fish, such as: infectious salmon anemia virus (ISAV), salmon pancreatic disease virus (SPDV), infectious pancreatic necrosis virus (IPNV), channel catfish virus (CCV), fish lymphocystis disease virus (FLDV), infectious hematopoietic necrosis virus (IHNV), koi herpesvirus, salmon picorna-like virus (also known as picorna-like virus of Atlantic salmon), landlocked salmon virus (LSV), Atlantic salmon rotavirus (ASR), trout strawberry disease virus (TSD), coho salmon tumor virus (CSTV), or viral hemorrhagic septicemia virus (VHSV).

Fungal immunogens may be derived from Dermatophytres, including: Epidermophyton floccusum, Microsporum audouini, Microsporum canis, Microsporum distortum, Microsporum equinum, Microsporum gypsum, Microsporum nanum, Trichophyton concentricum, Trichophyton equinum, Trichophyton gallinae, Trichophyton gypseum, Trichophyton megnini, Trichophyton mentagrophytes, Trichophyton quinckeanum, Trichophyton rubrum, Trichophyton schoenleini, Trichophyton tonsurans, Trichophyton verrucosum, T. verrucosum var. album, var. discoides, var. ochraceum, Trichophyton violaceum, and/or Trichophyton faviforme; or from Aspergillus fumigatus, Aspergillus flavus, Aspergillus niger, Aspergillus nidulans, Aspergillus terreus, Aspergillus sydowii, Aspergillus flavatus, Aspergillus glaucus, Blastoschizomyces capitatus, Candida albicans, Candida enolase, Candida tropicalis, Candida glabrata, Candida krusei, Candida parapsilosis, Candida stellatoidea, Candida kusei, Candida parakwsei, Candida lusitaniae, Candida pseudotropicalis, Candida guilliermondi, Cladosporium carrionii, Coccidioides immitis, Blastomyces dermatidis, Cryptococcus neoformans, Geotrichum clavatum, Histoplasma capsulatum, Klebsiella pneumoniae, Microsporidia, Encephalitozoon spp., Septata intestinalis and Enterocytozoon bieneusi; the less common are Brachiola spp., Microsporidium spp., Nosema spp., Pleistophora spp., Trachipleistophora spp., Vittaforma spp., Paracoccidioides brasiliensis, Pneumocystis carinii, Pythiumn insidiosum, Pityrosporum ovale, Sacharomyces cerevisae, Saccharomyces boulardii, Saccharomyces pombe, Scedosporium apiosperum, Sporothrix schenckii, Trichosporon beigelii, Toxoplasma gondii, Penicillium marneffei, Malassezia spp., Fonsecaea spp., Wangiella spp., Sporothrix spp., Basidiobolus spp., Conidiobolus spp., Rhizopus spp., Mucor spp., Absidia spp., Mortierella spp., Cunninghamella spp., Saksenaea spp., Alternaria spp., Curvularia spp., Helminthosporium spp., Fusarium spp., Aspergillus spp., Penicillium spp., Monolinia spp., Rhizoctonia spp., Paecilomyces spp., Pithomyces spp., and Cladosporium spp.

In some embodiments, the immunogen elicits an immune response against a parasite from the Plasmodium genus, such as P.falciparum, P.vivax, P.malariae, or P.ovale. Thus, the invention may be used for immunizing against malaria. In some embodiments the immunogen elicits an immune response against a parasite from the Caligidae family, particularly those from the Lepeophtheirus and Caligus genera, e.g., sea lice such as Lepeophtheirus salmonis or Caligus rogercresseyi.

In some embodiments, the immunogen elicits an immune response against: pollen allergens (tree-, herb-, weed-, and grass-pollen allergens); insect or arachnid allergens (inhalant, saliva, and venom allergens, e.g., mite allergens, cockroach, and midges allergens, hymenopthera venom allergens); animal hair and dandruff allergens (from, e.g., dog, cat, horse, rat, mouse, etc.); and food allergens (e.g., a gliadin). Important pollen allergens from trees, grasses, and herbs are such originating from the taxonomic orders of Fagales, Oleales, Pinales, and platanaceae including, but not limited to, birch (Betula), alder (Alnus), hazel (Corylus), hornbeam (Carpinus), and olive (Olea), cedar (Cryptomeria and Juniperus), plane tree (Platanus), the order of Poales including grasses of the genera Lolium, Phleum, Poa, Cynodon, Dactylis, Holcus, Phalaris, Secale, and Sorghum, the orders of Asterales and Urticales including herbs of the genera Ambrosia, Artemisia, and Parietaria. Other important inhalation allergens are those from house dust mites of the genus Dermatophagoides and Euroglyphus, storage mite, e.g., Lepidoglyphys, Glycyphagus, and Tyrophagus, those from cockroaches, midges, and fleas, e.g., Blatella, Periplaneta, Chironomus, and Ctenocepphalides, and those from mammals such as cat, dog, and horse, venom allergens including such originating from stinging or biting insects such as those from the taxonomic order of Hymenoptera including bees (Apidae), wasps (Vespidea), and ants (Formicoidae).

In some embodiments the immunogen is a tumor antigen selected from: (a) cancer-testis antigens such as NY-ESO-1, SSX2, SCP1 as well as RAGE, BAGE, GAGE, and MAGE family polypeptides, for example, GAGE-1, GAGE-2, MAGE-1, MAGE-2, MAGE-3, MAGE-4, MAGE-5, MAGE-6, and MAGE-12 (which can be used, for example, to address melanoma, lung, head and neck, NSCLC, breast, gastrointestinal, and bladder tumors; (b) mutated antigens, for example, p53 (associated with various solid tumors, e.g., colorectal, lung, head and neck cancer), p21/Ras (associated with, e.g., melanoma, pancreatic cancer, and colorectal cancer), CDK4 (associated with, e.g., melanoma), MUM1 (associated with, e.g., melanoma), caspase-8 (associated with, e.g., head and neck cancer), CIA 0205 (associated with, e.g., bladder cancer), HLA-A2-R1701, beta catenin (associated with, e.g., melanoma), TCR (associated with, e.g., T-cell non-Hodgkins lymphoma), BCR-abl (associated with, e.g., chronic myelogenous leukemia), triosephosphate isomerase, KIA 0205, CDC-27, and LDLR-FUT; (c) over-expressed antigens, for example, Galectin 4 (associated with, e.g., colorectal cancer), Galectin 9 (associated with, e.g., Hodgkin's disease), proteinase 3 (associated with, e.g., chronic myelogenous leukemia), WT 1 (associated with, e.g., various leukemias), carbonic anhydrase (associated with, e.g., renal cancer), aldolase A (associated with, e.g., lung cancer), PRAME (associated with, e.g., melanoma), HER-2/neu (associated with, e.g., breast, colon, lung, and ovarian cancer), mammaglobin, alpha-fetoprotein (associated with, e.g., hepatoma), KSA (associated with, e.g., colorectal cancer), gastrin (associated with, e.g., pancreatic and gastric cancer), telomerase catalytic protein, MUC-1 (associated with, e.g., breast and ovarian cancer), G-250 (associated with, e.g., renal cell carcinoma), p53 (associated with, e.g., breast, colon cancer), and carcinoembryonic antigen (associated with, e.g., breast cancer, lung cancer, and cancers of the gastrointestinal tract such as colorectal cancer); (d) shared antigens, for example, melanoma-melanocyte differentiation antigens such as MART-1/Melan A, gp100, MC1R, melanocyte-stimulating hormone receptor, tyrosinase, tyrosinase related protein-1/TRP1, and tyrosinase related protein-2/TRP2 (associated with, e.g., melanoma); (e) prostate associated antigens such as PAP, PSA, PSMA, PSH-P1, PSM-P1, PSM-P2, associated with, e.g., prostate cancer; (f) immunoglobulin idiotypes (associated with myeloma and B cell lymphomas, for example). In certain embodiments, tumor immunogens include, but are not limited to, p15, Hom/Me1-40, H-Ras, E2A-PRL, H4-RET, IGH-IGK, MYL-RAR, Epstein Barr virus antigens, EBNA, human papillomavirus (HPV) antigens, including E6 and E7, hepatitis B and C virus antigens, human T-cell lymphotropic virus antigens, TSP-180, p185erbB2, p180erbB-3, c-met, mn-23H1, TAG-72-4, CA 19-9, CA 72-4, CAM 17.1, NuMa, K-ras, p16, TAGE, PSCA, CT7, 43-9F, 5T4, 791 Tgp72, beta-HCG, BCA225, BTAA, CA 125, CA 15-3 (CA 27.29BCAA), CA 195, CA 242, CA-50, CAM43, CD68KP1, CO-029, FGF-5, Ga733 (EpCAM), HTgp-175, M344, MA-50, MG7-Ag, MOV18, NB/70K, NY-CO-1, RCAS1, SDCCAG16, TA-90 (Mac-2 binding protein/cyclophilin C-associated protein), TAAL6, TAG72, TLP, TPS, and the like.

Pharmaceutical Compositions

RNA will be administered as a component in a pharmaceutical composition for immunizing subjects against various diseases. These compositions will typically include a pharmaceutically acceptable carrier in addition to the RNA, often as part of a delivery system as described above. A thorough discussion of pharmaceutically acceptable carriers is available in reference 41.

A pharmaceutical composition of the invention may include one or more small molecule immunopotentiators. For example, the composition may include a TLR2 agonist (e.g., Pam3CSK4), a TLR4 agonist (e.g., an aminoalkyl glucosaminide phosphate, such as E6020), a TLR7 agonist (e.g., imiquimod), a TLR8 agonist (e.g., resiquimod), and/or a TLR9 agonist (e.g., IC31). Any such agonist ideally has a molecular weight of <2000 Da. Where a RNA is encapsulated, in some embodiments such agonist(s) are also encapsulated with the RNA, but in other embodiments they are unencapsulated. Where a RNA is adsorbed to a particle, in some embodiments such agonist(s) are also adsorbed with the RNA, but in other embodiments they are unadsorbed.

Pharmaceutical compositions of the invention may include the particles in plain water (e.g., w.f.i.) or in a buffer, e.g., a phosphate buffer, a Tris buffer, a borate buffer, a succinate buffer, a histidine buffer, or a citrate buffer. Buffer salts will typically be included in the 5-20 mM range.

Pharmaceutical compositions of the invention may have a pH between 5.0 and 9.5, e.g., between 6.0 and 8.0.

Compositions of the invention may include sodium salts (e.g., sodium chloride) to give tonicity. A concentration of 10±2 mg/ml NaCl is typical, e.g., about 9 mg/ml.

Compositions of the invention may include metal ion chelators. These can prolong RNA stability by removing ions which can accelerate phosphodiester hydrolysis. Thus, a composition may include one or more of EDTA, EGTA, BAPTA, pentetic acid, etc. Such chelators are typically present at between 10-500 μM, e.g., 0.1 mM. A citrate salt, such as sodium citrate, can also act as a chelator, while advantageously also providing buffering activity.

Pharmaceutical compositions of the invention may have an osmolality of between 200 mOsm/kg and 400 mOsm/kg, e.g., between 240-360 mOsm/kg, or between 290-310 mOsm/kg.

Pharmaceutical compositions of the invention may include one or more preservatives, such as thiomersal or 2-phenoxyethanol. Mercury-free compositions are preferred, and preservative-free vaccines can be prepared.

Pharmaceutical compositions of the invention are preferably sterile.

Pharmaceutical compositions of the invention are preferably non-pyrogenic, e.g., containing <1 EU (endotoxin unit, a standard measure) per dose, and preferably <0.1 EU per dose.

Pharmaceutical compositions of the invention are preferably gluten free.

Pharmaceutical compositions of the invention may be prepared in unit dose form. In some embodiments a unit dose may have a volume of between 0.1-1.0 ml, e.g., about 0.5 ml.

The compositions may be prepared as injectables, either as solutions or suspensions. The composition may be prepared for pulmonary administration, e.g., by an inhaler, using a fine spray. The composition may be prepared for nasal, aural, or ocular administration, e.g., as spray or drops. Injectables for intramuscular administration are typical.

The RNA content of compositions of the invention is expressed in terms of the amount of RNA per unit dose. RNA is readily quantified using available techniques.

RNAs are not delivered in combination with ribosomes and so pharmaceutical compositions of the invention are ribosome-free.

Methods of treatment and medical uses RNA delivery according to the invention is for eliciting an immune response in vivo against an immunogen of interest. The immune response is preferably protective and preferably involves antibodies and/or cell-mediated immunity. The method may raise a booster response.

By raising an immune response, the mammal can be protected against various diseases and/or infections, e.g., against bacterial and/or viral diseases as discussed above. RNA-containing compositions are immunogenic and are more preferably vaccine compositions. Vaccines according to the invention may either be prophylactic (i.e., to prevent infection) or therapeutic (i.e., to treat infection) but will typically be prophylactic.

The mammal immunized according to the present invention is a large mammal, such as a human or a large veterinary mammal (e.g., horses, cattle, deer, goats, pigs, camels, antelope, elephants).

Where the vaccine is for prophylactic use, the human is preferably a child (e.g., a toddler or infant) or a teenager; where the vaccine is for therapeutic use, the human is preferably a teenager or an adult. A vaccine intended for children may also be administered to adults, e.g., to assess safety, dosage, immunogenicity, etc.

Vaccines prepared according to the invention may be used to treat both children and adults. Thus, a human patient may be less than 1 year old, less than 5 years old, 1-5 years old, 5-15 years old, 15-55 years old, or at least 55 years old. Preferred patients for receiving the vaccines are the elderly (e.g., ≥50 years old, ≥60 years old, and preferably ≥65 years), the young (e.g., ≤5 years old), hospitalized patients, healthcare workers, armed service and military personnel, pregnant women, the chronically ill, or immunodeficient patients. The vaccines are not suitable solely for these groups, however, and may be used more generally in a population.

Compositions of the invention will generally be administered directly to a patient. Direct delivery may be accomplished by parenteral injection (e.g., subcutaneously, intraperitoneally, intravenously, intramuscularly, or to the interstitial space of a tissue; unlike reference 1, intraglossal injection is not typically used with the present invention), or mucosally, such as by rectal, oral (e.g., tablet, spray), vaginal, topical, transdermal or transcutaneous, intranasal, ocular, aural, pulmonary, or other mucosal administration. Injection may be via a needle (e.g., a hypodermic needle), but needle-free injection may alternatively be used. A typical intramuscular dose is 0.5 ml.

The invention may be used to elicit systemic and/or mucosal immunity, preferably to elicit an enhanced systemic and/or mucosal immunity.

Dosage can be by a single unit dose schedule or a multiple unit dose schedule. Multiple doses may be used in a primary immunization schedule and/or in a booster immunization schedule. In a multiple dose schedule the various doses may be given by the same or different routes, e.g., a parenteral prime and mucosal boost, a mucosal prime and parenteral boost, etc. Multiple doses will typically be administered at least 1 week apart (e.g., about 2 weeks, about 3 weeks, about 4 weeks, about 6 weeks, about 8 weeks, about 10 weeks, about 12 weeks, about 16 weeks, etc.). In one embodiment, unit doses may be administered approximately 6 weeks, 10 weeks, and 14 weeks after birth, e.g., at an age of 6 weeks, 10 weeks, and 14 weeks, as often used in the World Health Organization's Expanded Program on Immunization (“EPI”). In an alternative embodiment, two primary unit doses are administered about two months apart, e.g., about 7, 8, or 9 weeks apart, followed by one or more booster unit doses about 6 months to 1 year after the second primary dose, e.g., about 6, 8, 10, or 12 months after the second primary dose. In a further embodiment, three primary doses are administered about two months apart, e.g., about 7, 8, or 9 weeks apart, followed by one or more booster doses about 6 months to 1 year after the third primary dose, e.g., about 6, 8, 10, or 12 months after the third primary dose.

General Embodiments

In some embodiments of the invention, the RNA includes no modified nucleotides (see above). In other embodiments the RNA can optionally include at least one modified nucleotide, provided that one or more of the following features (already disclosed above) is also required:

-   -   A. Where the RNA is delivered with a liposome, the liposome         comprises DSDMA, DODMA, DLinDMA and/or DLenDMA.     -   B. Where the RNA is encapsulated in a liposome, the hydrophilic         portion of a lipid in the liposome is PEGylated.     -   C. Where the RNA is encapsulated in a liposome, at least 80% by         number of the liposomes have diameters in the range of 20-220         nm.     -   D. Where the RNA is delivered with a microparticle, the         microparticle is a non-toxic and biodegradable polymer         microparticle.     -   E. Where the RNA is delivered with a microparticle, the         microparticles have a diameter in the range of 0.02 μm to 8 μm.     -   F. Where the RNA is delivered with a microparticle, at least 80%         by number of the microparticles have a diameter in the range of         0.03-7 μm.     -   G. Where the RNA is delivered with a microparticle, the         composition is lyophilized.     -   H. Where the RNA is delivered with an emulsion, the emulsion         comprises a biodegradable oil (e.g., squalene).     -   I. Where the RNA is delivered with an emulsion, the emulsion         includes one or more cationic molecules, e.g., one or more         cationic lipids.     -   J. The RNA has a 3′ poly-A tail, and the immunogen can elicit an         immune response in vivo against a bacterium, a virus, a fungus,         or a parasite.     -   K. The RNA is delivered in combination with a metal ion chelator         with a delivery system selected from: (i) liposomes, (ii)         non-toxic and biodegradable polymer microparticles, (iii)         cationic submicron oil-in-water emulsions.         General

The practice of the present invention will employ, unless otherwise indicated, conventional methods of chemistry, biochemistry, molecular biology, immunology, and pharmacology, within the skill of the art. Such techniques are explained fully in the literature. See, e.g., references 42-48, etc.

The term “comprising” encompasses “including” as well as “consisting”, e.g., a composition “comprising” X may consist exclusively of X or may include something additional, e.g., X+Y.

The term “about” in relation to a numerical value x is optional and means, for example, x+10%.

The word “substantially” does not exclude “completely”, e.g., a composition which is “substantially free” from Y may be completely free from Y. Where necessary, the word “substantially” may be omitted from the definition of the invention.

References to charge, to cations, to anions, to zwitterions, etc., are taken at pH 7.

TLR3 is the Toll-like receptor 3. It is a single membrane-spanning receptor which plays a key role in the innate immune system. Known TLR3 agonists include poly(I:C). “TLR3” is the approved HGNC name for the gene encoding this receptor, and its unique HGNC ID is HGNC:11849. The RefSeq sequence for the human TLR3 gene is GI:2459625.

TLR7 is the Toll-like receptor 7. It is a single membrane-spanning receptor which plays a key role in the innate immune system. Known TLR7 agonists include, e.g., imiquimod. “TLR7” is the approved HGNC name for the gene encoding this receptor, and its unique HGNC ID is HGNC:15631. The RefSeq sequence for the human TLR7 gene is GI:67944638.

TLR8 is the Toll-like receptor 8. It is a single membrane-spanning receptor which plays a key role in the innate immune system. Known TLR8 agonists include, e.g., resiquimod. “TLR8” is the approved HGNC name for the gene encoding this receptor, and its unique HGNC ID is HGNC:15632. The RefSeq sequence for the human TLR8 gene is GI:20302165.

The RIG-I-like receptor (“RLR”) family includes various RNA helicases which play key roles in the innate immune system (see reference [49]). RLR-1 (also known as RIG-I or retinoic acid inducible gene I) has two caspase recruitment domains near its N-terminus. The approved HGNC name for the gene encoding the RLR-1 helicase is “DDX58” (for DEAD (Asp-Glu-Ala-Asp) box polypeptide 58) and the unique HGNC ID is HGNC:19102. The RefSeq sequence for the human RLR-1 gene is GI:77732514. RLR-2 (also known as MDA5 or melanoma differentiation-associated gene 5) also has two caspase recruitment domains near its N-terminus. The approved HGNC name for the gene encoding the RLR-2 helicase is “IFIH1” (for interferon induced with helicase C domain 1) and the unique HGNC ID is HGNC:18873. The RefSeq sequence for the human RLR-2 gene is GI: 27886567. RLR-3 (also known as LGP2 or laboratory of genetics and physiology 2) has no caspase recruitment domains. The approved HGNC name for the gene encoding the RLR-3 helicase is “DHX58” (for DEXH (Asp-Glu-X-His) box polypeptide 58) and the unique HGNC ID is HGNC:29517. The RefSeq sequence for the human RLR-3 gene is GI: 149408121.

PKR is a double-stranded RNA-dependent protein kinase. It plays a key role in the innate immune system. “EIF2AK2” (for eukaryotic translation initiation factor 2-alpha kinase 2) is the approved HGNC name for the gene encoding this enzyme, and its unique HGNC ID is HGNC:9437. The RefSeq sequence for the human PKR gene is GI:208431825.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 shows a gel with stained RNA. Lanes show: (1) markers, (2) naked replicon, (3) replicon after RNase treatment, (4) replicon encapsulated in liposome, (5) liposome after RNase treatment, (6) liposome treated with RNase then subjected to phenol/chloroform extraction.

FIG. 2 is an electron micrograph of liposomes.

FIG. 3 shows protein expression (as relative light units, RLU) at days 1, 3, and 6 after delivery of RNA as a virion-packaged replicon (squares), naked RNA (triangles), or as microparticles (circles).

FIG. 4 shows a gel with stained RNA. Lanes show: (1) markers, (2) naked replicon, (3) replicon encapsulated in liposome, (4) liposome treated with RNase then subjected to phenol/chloroform extraction.

FIG. 5 shows protein expression at days 1, 3, and 6 after delivery of RNA as a virion-packaged replicon (squares), as naked RNA (diamonds), or in liposomes (+=0.1 μg, x=1 μg).

FIG. 6 shows protein expression at days 1, 3, and 6 after delivery of four different doses of liposome-encapsulated RNA.

FIG. 7 shows anti-F IgG titers in animals receiving virion-packaged replicon (VRP or VSRP), 1 μg naked RNA, and 1Ig liposome-encapsulated RNA.

FIG. 8 shows anti-F IgG titers in animals receiving VRP, I pg naked RNA, and 0.1 μg or 1 μg liposome-encapsulated RNA.

FIG. 9 shows neutralizing antibody titers in animals receiving VRP or either 0.1 μg or 1 μg liposome-encapsulated RNA.

FIG. 10 shows expression levels after delivery of a replicon as naked RNA (circles), liposome-encapsulated RNA (triangle & square), or as a lipoplex (inverted triangle).

FIG. 11 shows F-specific IgG titers (2 weeks after second dose) after delivery of a replicon as naked RNA (0.01-1 μg), liposome-encapsulated RNA (0.01-10 μg), or packaged as a virion (VRP, 10⁶ infectious units or IU).

FIG. 12 shows F-specific IgG titers (circles) and PRNT titers (squares) after delivery of a replicon as naked RNA (1 μg), liposome-encapsulated RNA (0.1 or 1 μg), or packaged as a virion (VRP, 10⁶ IU). Titers in naïve mice are also shown. Solid lines show geometric means.

FIG. 13 shows intracellular cytokine production after restimulation with synthetic peptides representing the major epitopes in the F protein, 4 weeks after a second dose. The y-axis shows the % cytokine+ of CD8+CD4-.

FIGS. 14A & 14B show F-specific IgG titers (mean log₁₀ titers±std dev) over 63 days (FIG. 14A) and 210 days (FIG. 14B) after immunization of calves. The four lines are easily distinguished at day 63 and are, from bottom to top: PBS negative control; liposome-delivered RNA; emulsion-delivered RNA; and the “Triangle 4” product.

MODES FOR CARRYING OUT THE INVENTION

RNA replicons

Various replicons are used below. In general, these are based on a hybrid alphavirus genome with non-structural proteins from Venezuelan equine encephalitis virus (VEEV), a packaging signal from Sindbis virus, and a 3′ UTR from Sindbis virus or a VEEV mutant. The replicon is about 10 kb long and has a poly-A tail.

Plasmid DNA encoding alphavirus replicons (named: pT7-mVEEV-FL.RSVF or A317; pT7-mVEEV-SEAP or A306; pSP6-VCR-GFP or A50) served as a template for synthesis of RNA in vitro. The replicons contain the alphavirus genetic elements required for RNA replication but lack those encoding gene products necessary for particle assembly; the structural proteins are instead replaced by a protein of interest (either a reporter, such as SEAP or GFP, or an immunogen, such as full-length RSV F protein) and so the replicons are incapable of inducing the generation of infectious particles. A bacteriophage (T7 or SP6) promoter upstream of the alphavirus cDNA facilitates the synthesis of the replicon RNA in vitro and a hepatitis delta virus (HDV) ribozyme immediately downstream of the poly(A)-tail generates the correct 3′-end through its self-cleaving activity.

Following linearization of the plasmid DNA downstream of the HDV ribozyme with a suitable restriction endonuclease, run-off transcripts were synthesized in vitro using T7 or SP6 bacteriophage derived DNA-dependent RNA polymerase. Transcriptions were performed for 2 hours at 37° C. in the presence of 7.5 mM (T7 RNA polymerase) or 5 mM (SP6 RNA polymerase) of each of the nucleoside triphosphates (ATP, CTP, GTP, and UTP) following the instructions provided by the manufacturer (Ambion). Following transcription, the template DNA was digested with TURBO DNase (Ambion). The replicon RNA was precipitated with LiCl and reconstituted in nuclease-free water. Uncapped RNA was capped post-transcriptionally with Vaccinia Capping Enzyme (VCE) using the SCRIPTCAP™ m7G Capping System (Epicentre Biotechnologies) as outlined in the user manual; replicons capped in this way are given the “v” prefix, e.g., vA317 is the A317 replicon capped by VCE. Post-transcriptionally capped RNA was precipitated with LiCl and reconstituted in nuclease-free water. The concentration of the RNA samples was determined by measuring OD_(260nm). Integrity of the in vitro transcripts was confirmed by denaturing agarose gel electrophoresis.

PLG adsorption

Microparticles were made using 500 mg of PLG RG503 (50:50 lactide/glycolide molar ratio, MW ˜30 kDa) and 20 mg DOTAP using an Omni Macro Homogenizer. The particle suspension was shaken at 150 rpm overnight and then filtered through a 40 μm sterile filter for storage at 2-8° C. Self-replicating RNA was adsorbed to the particles. To prepare 1 mL of PLG/RNA suspension the required volume of PLG particle suspension was added to a vial and nuclease-free water was added to bring the volume to 900 μL. 100 μL RNA (10 μg/mL) was added dropwise to the PLG suspension, with constant shaking. PLG/RNA was incubated at room temperature for 30 min. For 1 mL of reconstituted suspension, 45 mg mannitol, 15 mg sucrose, and 250-500 μg of PVA were added.

The vials were frozen at −80° C. and lyophilized.

To evaluate RNA adsorption, 100 μL particle suspension was centrifuged at 10,000 rpm for 5 min and supernatant was collected. PLG/RNA was reconstituted using 1 mL nuclease-free water. To 100 μL particle suspension (1 μg RNA), 1 mg heparin sulfate was added. The mixture was vortexed and allowed to sit at room temperature for 30 min for RNA desorption. Particle suspension was centrifuged and supernatant was collected.

For RNAse stability, 100 μL particle suspension was incubated with 6.4 mAU of RNase A at room temperature for 30 min. RNAse was inactivated with 0.126 mAU of Proteinase K at 55° C. for 10 min. 1 mg of heparin sulfate was added to desorb the RNA followed by centrifugation. The supernatant samples containing RNA were mixed with formaldehyde load dye, heated at 65° C. for 10 min, and analyzed using a 1% denaturing gel (460 ng RNA loaded per lane).

To assess expression, BALB/c mice were immunized with 1 μg RNA in 100 μL intramuscular injection volume (50 μL/leg) on day 0. Sera were collected on days 1, 3, and 6. Protein expression was determined using a chemiluminescence assay. As shown in FIG. 3 , expression was higher when RNA was delivered by PLG (triangles) than without any delivery particle (circles).

Cationic Nanoemulsion

An oil-in-water emulsion was prepared by microfluidizing squalene, span 85, polysorbate 80, and varying amounts of DOTAP. Briefly, oil soluble components (squalene, span 85, cationic lipids, lipid surfactants) were combined in a beaker, lipid components were dissolved in organic solvent. The resulting lipid solution was added directly to the oil phase. The solvent was allowed to evaporate at room temperature for 2 hours in a fume hood prior to combining the aqueous phase and homogenizing the sample to provide a homogeneous feedstock. The primary emulsions were passed three to five times through a MICROFLUIDIZER™ with an ice bath cooling coil. The batch samples were removed from the unit and stored at 4° C.

This emulsion is thus similar to the commercial MF59™ adjuvant, but supplemented by a cationic DOTAP to provide a cationic nanoemulsion (“CNE”). The final composition of emulsion “CNE17” was squalene (4.3% by weight), span 85 (0.5% by weight), polysorbate 80 (0.5% by weight), DOTAP (1.4 mg/ml), in 10 mM citrate buffer, pH 6.5.

RNA adsorbs to the surface of the oil droplets in these cationic emulsions. To adsorb RNA, a RNA solution is diluted to the appropriate concentration in RNase free water and then added directly into an equal volume of emulsion while vortexing lightly. The solution is allowed to sit at room temperature for approximately 2 hours to allow adsorption. The resulting solution is diluted to the required RNA concentration prior to administration.

Liposomal Encapsulation

RNA was encapsulated in liposomes made by the method of references 11 and 50. The liposomes were made of 10% DSPC (zwitterionic), 40% DlinDMA (cationic), 48% cholesterol, and 2% PEG-conjugated DMG (2 kDa PEG). These proportions refer to the % moles in the total liposome.

DlinDMA (1,2-dilinoleyloxy-N,N-dimethyl-3-aminopropane) was synthesized using the procedure of reference 6. DSPC (1,2-distearoyl-sn-glycero-3-phosphocholine) was purchased from Genzyme.

Cholesterol was obtained from Sigma-Aldrich. PEG-conjugated DMG (1,2-dimyristoyl-sn-glycero-3-phosphoethanolamine-N-[methoxy(polyethylene glycol), ammonium salt), DOTAP (1,2-dioleoyl-3-trimethylammonium-propane, chloride salt), and DC-chol (3β-[N-(N′,N′-dimethylaminoethane)-carbamoyl]cholesterol hydrochloride) were from Avanti Polar Lipids.

Briefly, lipids were dissolved in ethanol (2 mL), a RNA replicon was dissolved in buffer (2 mL, 100 mM sodium citrate, pH 6), and these were mixed with 2 mL of buffer followed by 1 hour of equilibration.

The mixture was diluted with 6 mL buffer then filtered. The resulting product contained liposomes, with ˜95% encapsulation efficiency.

For example, in one particular method, fresh lipid stock solutions were prepared in ethanol. 37 mg of DlinDMA, 11.8 mg of DSPC, 27.8 mg of cholesterol, and 8.07 mg of PEG-DMG were weighed and dissolved in 7.55 mL of ethanol. The freshly prepared lipid stock solution was gently rocked at 37° C. for about 15 min to form a homogenous mixture. Then, 755 μL of the stock was added to 1.245 mL ethanol to make a working lipid stock solution of 2 mL. This amount of lipids was used to form liposomes with 250 μg RNA. A 2 mL working solution of RNA was also prepared from a stock solution of ˜1 μg/μL in 100 mM citrate buffer (pH 6). Three 20 mL glass vials (with stir bars) were rinsed with RNASE AWAY™ solution (Molecular BioProducts) and washed with plenty of MilliQ water before use to decontaminate the vials of RNases. One of the vials was used for the RNA working solution and the others for collecting the lipid and RNA mixes (as described later). The working lipid and RNA solutions were heated at 37° C. for 10 min before being loaded into 3 cc LUER-LOK™ syringes. 2 mL citrate buffer (pH 6) was loaded in another 3 cc syringe. Syringes containing RNA and the lipids were connected to a T mixer (PEEK™ 500 μm ID junction, Idex Health Science) using FEP tubing (fluorinated ethylene-propylene; all FEP tubing used had a 2 mm internal diameter and a 3 mm outer diameter; obtained from Idex Health Science). The outlet from the T mixer was also FEP tubing. The third syringe containing the citrate buffer was connected to a separate piece of tubing. All syringes were then driven at a flow rate of 7 mL/min using a syringe pump. The tube outlets were positioned to collect the mixtures in a 20 mL glass vial (while stirring). The stir bar was taken out and the ethanol/aqueous solution was allowed to equilibrate to room temperature for 1 h. 4 mL of the mixture was loaded into a 5 cc syringe, which was connected to a piece of FEP tubing and in another 5 cc syringe connected to an equal length of FEP tubing, an equal amount of 100 mM citrate buffer (pH 6) was loaded. The two syringes were driven at 7 mL/min flow rate using the syringe pump and the final mixture collected in a 20 mL glass vial (while stirring). Next, the mixture collected from the second mixing step (liposomes) were passed through a Mustang Q membrane (an anion-exchange support that binds and removes anionic molecules, obtained from Pall Corporation). Before using this membrane for the liposomes, 4 mL of 1 M NaOH, 4 mL of 1 M NaCl, and 10 mL of 100 mM citrate buffer (pH 6) were successively passed through it. Liposomes were warmed for 10 min at 37° C. before passing through the membrane. Next, liposomes were concentrated to 2 mL and dialyzed against 10-15 volumes of 1×PBS using by tangential flow filtration before recovering the final product. The TFF system and hollow fiber filtration membranes were purchased from Spectrum Labs (Rancho Dominguez) and were used according to the manufacturer's guidelines. Polysulfone hollow fiber filtration membranes with a 100 kDa pore size cutoff and 8 cm² surface area were used. For in vitro and in vivo experiments formulations were diluted to the required RNA concentration with 1×PBS.

FIG. 2 shows an example electron micrograph of liposomes prepared by these methods. These liposomes contain encapsulated RNA encoding full-length RSV F antigen. Dynamic light scattering of one batch showed an average diameter of 141 nm (by intensity) or 78 nm (by number).

The percentage of encapsulated RNA and RNA concentration were determined by QUANT-IT™ RIBOGREEN™ RNA reagent kit (Invitrogen), following manufacturer's instructions. The ribosomal RNA standard provided in the kit was used to generate a standard curve. Liposomes were diluted 10x or 100x in 1X TE buffer (from kit) before addition of the dye. Separately, liposomes were diluted 10x or 100x in 1X TE buffer containing 0.5% Triton X before addition of the dye (to disrupt the liposomes and thus to assay total RNA). Thereafter an equal amount of dye was added to each solution and then ˜180 μL of each solution after dye addition was loaded in duplicate into a 96 well tissue culture plate. The fluorescence (Ex 485 nm, Em 528 nm) was read on a microplate reader. All liposome formulations were dosed in vivo based on the encapsulated amount of RNA.

Encapsulation in liposomes was shown to protect RNA from RNase digestion. Experiments used 3.8 mAU of RNase A per microgram of RNA, incubated for 30 minutes at room temperature. RNase was inactivated with Proteinase K at 55° C. for 10 minutes. A 1:1 v/v mixture of sample to 25:24:1 v/v/v, phenol:chloroform:isoamyl alcohol was then added to extract the RNA from the lipids into the aqueous phase. Samples were mixed by vortexing for a few seconds and then placed on a centrifuge for 15 minutes at 12 k RPM. The aqueous phase (containing the RNA) was removed and used to analyze the RNA. Prior to loading (400 ng RNA per well), all the samples were incubated with formaldehyde loading dye, denatured for 10 minutes at 65° C., and cooled to room temperature.

Ambion MILLENNIUM™ markers were used to approximate the molecular weight of the RNA construct. The gel was run at 90 V. The gel was stained using 0.1% SYBR™ gold according to the manufacturer's guidelines in water by rocking at room temperature for 1 hour. FIG. 1 shows that RNase completely digests RNA in the absence of encapsulation (lane 3). RNA is undetectable after encapsulation (lane 4), and no change is seen if these liposomes are treated with RNase (lane 4).

After RNase-treated liposomes are subjected to phenol extraction, undigested RNA is seen (lane 6). Even after 1 week at 4° C., the RNA could be seen without any fragmentation (FIG. 4 , arrow).

Protein expression in vivo was unchanged after 6 weeks at 4° C. and one freeze-thaw cycle. Thus, liposome-encapsulated RNA is stable.

To assess in vivo expression of the RNA, a reporter enzyme (SEAP; secreted alkaline phosphatase) was encoded in the replicon, rather than an immunogen. Expression levels were measured in sera diluted 1:4 in 1X Phospha-Light dilution buffer using a chemiluminescent alkaline phosphate substrate. 8-10 week old BALB/c mice (5/group) were injected intramuscularly on day 0, 50 L per leg with 0.1 μg or 1 μg RNA dose. The same vector was also administered without the liposomes (in RNase free 1X PBS) at 1 μg. Virion-packaged replicons were also tested. Virion-packaged replicons used herein (referred to as “VRPs”) were obtained by the methods of reference 51, where the alphavirus replicon is derived from the mutant VEEV or a chimera derived from the genome of VEEV engineered to contain the 3′ UTR of Sindbis virus and a Sindbis virus packaging signal (PS), packaged by co-electroporating them into BHK cells with defective helper RNAs encoding the Sindbis virus capsid and glycoprotein genes.

As shown in FIG. 5 , encapsulation increased SEAP levels by about ½ log at the 1 μg dose, and at day 6 expression from a 0.1 μg encapsulated dose matched levels seen with 1 μg unencapsulated dose.

By day 3, expression levels exceeded those achieved with VRPs (squares). Thus, expression increased when the RNA was formulated in the liposomes relative to the naked RNA control, even at a 10x lower dose. Expression was also higher relative to the VRP control, but the kinetics of expression were very different (see FIG. 5 ). Delivery of the RNA with electroporation resulted in increased expression relative to the naked RNA control, but these levels were lower than with liposomes.

To assess whether the effect seen in the liposome groups was due merely to the liposome components, or was linked to the encapsulation, the replicon was administered in encapsulated form (with two different purification protocols, 0.1 μg RNA), or mixed with the liposomes after their formation (a non-encapsulated “lipoplex”, 0.1 μg RNA), or as naked RNA (1 μg). FIG. 10 shows that the lipoplex gave the lowest levels of expression, showing that encapsulation is essential for potent expression.

Further SEAP experiments showed a clear dose response in vivo, with expression seen after delivery of as little as 1 ng RNA (FIG. 6 ). Further experiments comparing expression from encapsulated and naked replicons indicated that 0.01 μg encapsulated RNA was equivalent to 1 μg of naked RNA. At a 0.5 μg dose of RNA, the encapsulated material gave a 12-fold higher expression at day 6; at a 0.1 μg dose, levels were 24-fold higher at day 6.

Rather than looking at average levels in the group, individual animals were also studied. Whereas several animals were non-responders to naked replicons, encapsulation eliminated non-responders.

Further experiments replaced DlinDMA with DOTAP. Although the DOTAP liposomes gave better expression than naked replicon, they were inferior to the DlinDMA liposomes (2-to 3-fold difference at day 1).

To assess in vivo immunogenicity, a replicon was constructed to express full-length F protein from respiratory syncytial virus (RSV). This was delivered naked (1 μg), encapsulated in liposomes (0.1 or 1 μg), or packaged in virions (10⁶ IU; “VRP”) at days 0 and 21. FIG. 7 shows anti-F IgG titers 2 weeks after the second dose, and the liposomes clearly enhance immunogenicity. FIG. 8 shows titers 2 weeks later, by which point there was no statistical difference between the encapsulated RNA at 0.1 μg, the encapsulated RNA at 1 μg, or the VRP group. Neutralization titers (measured as 60% plaque reduction, “PRNT60”) were not significantly different in these three groups 2 weeks after the second dose (FIG. 9 ). FIG. 12 shows both IgG and PRNT titers 4 weeks after the second dose.

FIG. 13 confirms that the RNA elicits a robust CD8 T cell response.

Further experiments compared F-specific IgG titers in mice receiving VRP, 0.1 μg liposome-encapsulated RNA, or 1 μg liposome-encapsulated RNA. Titer ratios (VRP:liposome) at various times after the second dose were as follows:

2 weeks 4 weeks 8 weeks 0.1 μg 2.9 1.0 1.1   1 μg 2.3 0.9 0.9 Thus, the liposome-encapsulated RNA induces essentially the same magnitude of immune response as seen with virion delivery.

Further experiments showed superior F-specific IgG responses with a 10 μg dose, equivalent responses for 1 μg and 0.1 μg doses, and a lower response with a 0.01 μg dose. FIG. 11 shows IgG titers in mice receiving the replicon in naked form at 3 different doses, in liposomes at 4 different doses, or as VRP (10⁶ IU). The response seen with 1 μg liposome-encapsulated RNA was statistically insignificant (ANOVA) when compared to VRP, but the higher response seen with 10 μg liposome-encapsulated RNA was statistically significant (p<0.05) when compared to both of these groups.

A further study confirmed that the 0.1 μg of liposome-encapsulated RNA gave much higher anti-F IgG responses (15 days post-second dose) than 0.1 μg of delivered DNA, and even was more immunogenic than 20 μg plasmid DNA encoding the F antigen, delivered by electroporation (ELGEN™ DNA Delivery System, Inovio).

A further study was performed in cotton rats (Sigmodon hispidis) instead of mice. At a 1 μg dose liposome encapsulation increased F-specific IgG titers by 8.3-fold compared to naked RNA and increased PRNT titers by 9.5-fold. The magnitude of the antibody response was equivalent to that induced by 5×10⁶ IU VRP. Both naked and liposome-encapsulated RNA were able to protect the cotton rats from RSV challenge (1×10⁵ plaque forming units), reducing lung viral load by at least 3.5 logs. Encapsulation increased the reduction by about 2-fold.

Host defense responses at higher RNA doses

Mice were used to see if host defense responses (innate or adaptive immunity) might limit the immune response to encoded antigens at higher RNA doses.

Three different RNAs were used for this study: (i) ‘vA317’ replicon that expresses RSV-F, i.e., the surface fusion glycoprotein of RSV; (ii) ‘vA17’ replicon that expresses GFP; and (iii) ‘vA336’ that is replication-defective and encodes GFP.

RNAs were delivered either naked or with liposomes made with 40% DlinDMA, 10% DSPC, 48% Chol, and 2% PEG-DMG (proportions are % moles of total liposome). These liposomes were prepared in 75 μg batches. Fresh lipid stock solutions in ethanol were prepared. 37 mg of DlinDMA, 11.8 mg of DSPC, 27.8 mg of cholesterol, and 8.07 mg of PEG-DMG were weighed and dissolved in 7.55 mL of ethanol. The freshly prepared lipid stock solution was gently rocked at 37° C. for about 15 min to form a homogenous mixture. Then, 226.7 μL of the stock was added to 1.773 mL ethanol to make a working lipid stock solution of 2 mL. This amount of lipids was used to form liposomes with 75 μg RNA. A 2 mL working solution of RNA was also prepared from a stock solution of ˜ 1 μg/μL in 100 mM citrate buffer (pH 6). Three 20 mL glass vials (with stir bars) were rinsed with RNASE AWAY™ solution (Molecular BioProducts) and washed with plenty of MilliQ water before use to decontaminate the vials of RNases. One of the vials was used for the RNA working solution and the others for collecting the lipid and RNA mixes (as described later). The working lipid and RNA solutions were heated at 37° C. for 10 min before being loaded into 3 cc syringes. 2 mL of citrate buffer (pH 6) was loaded in another 3 cc syringe. Syringes containing RNA and the lipids were connected to a T mixer (PEEK™ 500 μm ID junction) using FEP tubing.

The outlet from the T mixer was also FEP tubing. The third syringe containing the citrate buffer was connected to a separate piece of tubing. All syringes were then driven at a flow rate of 7 mL/min using a syringe pump. The tube outlets were positioned to collect the mixtures in a 20 mL glass vial (while stirring). The stir bar was taken out and the ethanol/aqueous solution was allowed to equilibrate to room temperature for 1 h. Then, the mixture was loaded in a 5 cc syringe, which was fitted to a piece of FEP tubing and in another 5 cc syringe with equal length of FEP tubing, an equal volume of 100 mM citrate buffer (pH 6) was loaded. The two syringes were driven at 7 mL/min flow rate using a syringe pump and the final mixture collected in a 20 mL glass vial (while stirring). Next, liposomes were concentrated to 2 mL and dialyzed against 10-15 volumes of 1×PBS using TFF before recovering the final product. The TFF system and hollow fiber filtration membranes were purchased from Spectrum Labs and were used according to the manufacturer's guidelines. Polyethersulfone (PES) hollow fiber filtration membranes (part number P-C1-100E-100-01N) with a 100 kDa pore size cutoff and 20 cm² surface area were used. For in vitro and in vivo experiments, formulations were diluted to the required RNA concentration with 1×PBS.

The four liposome formulations had the following characteristics:

RNA Particle Size Zav (nm) Polydispersity RNA Encapsulation vA317 155.7 0.113 86.6% vA17 148.4 0.139  92% vA336 145.1 0.143 92.9% Empty 147.9 0.147 —

BALB/c mice, 5 animals per group, were given bilateral intramuscular vaccinations (50 μL per leg) on days 0 and 21 with:

-   -   Group 1 naked self-replicating RSV-F RNA (vA317, 0.1 μg)     -   Group 2 self-replicating RSV-F RNA (vA317, 0.1 μg) encapsulated         in liposomes     -   Group 3 self-replicating RSV-F RNA (vA317, 0.1 μg) added to         empty liposomes     -   Group 4 a mixture of self-replicating RSV-F RNA (vA317, 0.1 μg)         and self-replicating GFP RNA (vA17, 10 μg)     -   Group 5 a mixture of self-replicating RSV-F RNA (vA317, 0.1 μg)         and replication-defective GFP RNA (vA336, 10 μg)     -   Group 6 a mixture of self-replicating RSV-F RNA formulated in         liposomes (vA317, 0.1 μg) and self-replicating GFP RNA (vA17, 10         μg)     -   Group 7 a mixture of self-replicating RSV-F RNA formulated in         liposomes (vA317, 0.1 μg) and replication-defective GFP RNA         (vA336, 10 μg)     -   Group 8 a mixture of self-replicating RSV-F RNA formulated in         liposomes (vA317, 0.1 μg) and self-replicating GFP RNA         formulated in liposomes (vA17, 1 μg)     -   Group 9 a mixture of self-replicating RSV-F RNA formulated in         liposomes (vA317, 0.1 μg) and replication-defective GFP RNA         formulated in liposomes (vA336, 1 μg)     -   Group 10 F subunit protein (5 μg)

Serum was collected for antibody analysis on days 14, 35, and 51. F-specific serum IgG titers (GMT) were measured; if an individual animal had a titer of <25 (limit of detection), it was assigned a titer of 5. In addition, spleens were harvested from mice at day 51 for T cell analysis, to determine cells which were cytokine-positive and specific for RSV F51-66 peptide (CD4+) or for RSV F peptides F85-93 and F249-258 (CD8+).

IgG titers were as follows in the 10 groups and in non-immunized control mice:

Day 1 2 3 4 5 6 7 8 9 10 — 14 22 1819 5 5 24 174 1130 44 347 5 5 35 290 32533 9 5 746 6887 13171 773 4364 19877 5 51 463 30511 18 10 1076 7201 14426 922 4697 20853 5

RSV serum neutralization titers at day 51 were as follows:

Day 1 2 3 4 5 6 7 8 9 10 51 35 50 24 25 31 31 54 34 24 38

Animals showing RSV F-specific CD4+ splenic T cells on day 51 were as follows, where a number (% positive cells) is given only if the stimulated response was statistically significantly above zero:

Cytokine 1 2 3 4 5 6 7 8 9 10 IFN-γ 0.04 0.02 0.02 IL2 0.02 0.06 0.02 0.02 0.02 0.02 IL5 0.01 TNFα 0.03 0.05 0.02 0.02

Animals showing RSV F-specific CD8+ splenic T cells on day 51 were as follows, where a number is given only if the stimulated response was statistically significantly above zero:

Cytokine 1 2 3 4 5 6 7 8 9 10 IFN-γ 0.37 0.87 0.37 0.40 0.49 0.06 0.54 IL2 0.11 0.40 0.15 0.18 0.20 0.03 0.23 0.04 IL5 TNFα 0.29 0.79 0.35 0.42 0.40 0.53 0.06

These results show that host defense responses can limit the immune response to the delivered vector. For instance, groups 2 and 6-9 used the same self-replicating antigen-encoding vector, delivered in liposomes, but groups 6-9 also had a 100-fold or 10-fold excess of GFP-encoding vector, delivered either naked or inside liposomes, and either self-replicating or replication-defective. The extra RNA reduced anti-RSV responses, particularly if it was self-replicating and/or encapsulated.

Further experiments aimed to see if host responses to RNA might limit protein expression. Thus, expression was followed for only 6 days, before an adaptive response (antibodies, T cells) would be apparent. The “vA306” replicon encodes SEAP; the “vA17” replicon encodes GFP; the “vA336” replicon encodes GFP but cannot self-replicate; the “vA336*” replicon is the same as vA336 but was prepared with 10% of uridines replaced with 5-methyluridine; the “vA336**” replicon is the same as va336 but 100% of its uridine residues are MSU. BALB/c mice were given bilateral intramuscular vaccinations (50 μL per leg) on day 0. Animals, 35 total, were divided into 7 groups (5 animals per group) and were immunized as follows:

-   -   Group 1 Naïve control.     -   Group 2 were given bilateral intramuscular vaccinations (50 μL         per leg) on day 0 with RNA (vA306, 0.1 μg, SEAP) formulated in         liposomes mixed with self-replicating RNA (vA17, 1.0 μg, GFP)         formulated in liposomes.     -   Group 3 were given bilateral intramuscular vaccinations (50 μL         per leg) on day 0 with RNA (vA306, 0.1 μg, SEAP) formulated in         liposomes mixed with non-replicating RNA (vA336, 1.0 μg, GFP)         formulated in liposomes.     -   Group 4 were given bilateral intramuscular vaccinations (50 μL         per leg) on day 0 with RNA (vA306, 0.1 μg, SEAP) formulated in         liposomes mixed with non-replicating RNA (vA336*, 1.0 μg, GFP)         formulated in liposomes.

Group 5 were given bilateral intramuscular vaccinations (50 μL per leg) on day 0 with RNA (vA306, 0.1 μg, SEAP) formulated in liposomes mixed with non-replicating RNA (vA336**, 1.0 μg, GFP) formulated in liposomes.

-   -   Group 6 were given bilateral intramuscular vaccinations (50 μL         per leg) on day 0 with RNA (vA306, 0.1 μg, SEAP) formulated in         liposomes mixed with empty liposomes at the same lipid dose as         groups 2-5.     -   Group 7 were given bilateral intramuscular vaccinations (50 μL         per leg) on day 0 with RNA (vA306, 0.1 μg, SEAP) formulated in         liposomes mixed with self-replicating RNA (vA17, 1.0 μg, GFP)         formulated in liposomes.

Serum SEAP activity (relative light units) at days 0, 3, and 6 were as follows (GMT): Day 1 Day 3 Day 6

Day 1 Day 3 Day 6 1 898 1170 2670 2 1428 4219 28641 3 1702 9250 150472 4 1555 8005 76043 5 1605 8822 91019 6 10005 14640 93909 7 1757 6248 53497

Replication-competent RNA encoding GFP suppressed the expression of SEAP more than replication-defective GFP RNA, suggesting a strong host defense response against replicating RNA which leads to suppression of SEAP expression. It is possible that interferons induced in response to the GFP RNA suppressed the expression of SEAP. Under the host response/suppression model, blocking host recognition of RNA would be expected to lead to increased SEAP expression, but 5′ methylation of U residues in the GFP RNA was not associated with increased SEAP, suggesting that host recognition of RNA was insensitive to 5′ methylation.

Delivery Volume

Hydrodynamic delivery employs the force generated by the rapid injection of a large volume of solution to overcome the physical barriers of cell membranes which prevent large and membrane-impermeable compounds from entering cells. This phenomenon has previously been shown to be useful for the intracellular delivery of DNA vaccines.

A typical mouse delivery volume for intramuscular injection is 50 μL into the hind leg, which is a relatively high volume for a mouse leg muscle. In contrast, a human intramuscular dose of ˜0.5 mL is relatively small. If immunogenicity in mice would be volume-dependent, then the replicon vaccines' efficacy might be due, at least in part, on hydrodynamic forces, which would not be encouraging for use of the same vaccines in humans and larger animals.

The vA317 replicon was delivered to BALB/c mice, 10 per group, by bilateral intramuscular vaccinations (5 or 50 μL per leg) on day 0 and 21:

-   -   Group 1 received naked replicon, 0.2 μg in 50 μL per leg     -   Group 2 received naked replicon, 0.2 μg in 5 μL per leg     -   Group 3 received emulsion-formulated replicon (0.2 μg, 50 μL per         leg)     -   Group 4 received emulsion-formulated replicon (0.2 μg, 5 μL per         leg)     -   Group 5 received liposome-formulated replicon (0.2 μg, 50 μL per         leg)     -   Group 6 received liposome-formulated replicon (0.2 μg, 5 μL per         leg)

Serum was collected for antibody analysis on days 14 and 35. F-specific serum IgG GMTs were:

Day 1 2 3 4 5 6 14 42 21 783 760 2669 2610 35 241 154 2316 2951 17655 18516

Thus, immunogenicity of the formulated replicon did not vary according to the delivered volume, thus indicating that these RNA vaccines do not rely on hydrodynamic delivery for their efficacy.

Large Mammal Study

A large-animal study was performed in cattle. Calves (4-6 weeks old, ˜60-80 kg, 5 per group) were immunized with 66 μg of replicon vA317 encoding full-length RSV F protein at days 0, 21, 86, and 146. The replicons were formulated either inside liposomes or with the CNE17 emulsion. PBS alone was used as a negative control, and a licensed vaccine was used as a positive control (“Triangle 4” from Fort Dodge, containing killed virus). All calves received 15 μg F protein adjuvanted with the MF59TM emulsion on day 146. One cow was mistakenly vaccinated with the CNE17-based vaccine on day 86 instead of Triangle 4 and so its data were excluded from day 100 onwards.

The RNA vaccines encoded human RSV F whereas the “Triangle 4” vaccine contains bovine RSV F, but the RSV F protein is highly conserved between BRSV and HRSV.

The liposomes had the same proportion of DlinDMA, DSPC, cholesterol, and PEG-DMG as mentioned above. Fresh lipid stock solutions in ethanol were prepared. 37 mg of DlinDMA, 11.8 mg of DSPC, 27.8 mg of cholesterol, and 8.07 mg of PEG-DMG were weighed and dissolved in 7.55 mL of ethanol. The freshly prepared lipid stock solution was gently rocked at 37° C. for about 15 min to form a homogenous mixture. Then, 226.7 μL of the stock was added to 1.773 mL ethanol to make a working lipid stock solution of 2 mL. A 2 mL working solution of RNA was also prepared from a stock solution of ˜1 μg/μL in 100 mM citrate buffer (pH 6). Three 20 mL glass vials (with stir bars) were rinsed with RNASE AWAY™ solution (Molecular BioProducts) and washed with plenty of MilliQ water before use to decontaminate the vials of RNAses. One of the vials was used for the RNA working solution and the others for collecting the lipid and RNA mixes (as described later). The working lipid and RNA solutions were heated at 37° C. for 10 min before being loaded into 3 cc syringes. 2 mL of citrate buffer (pH 6) was loaded in another 3 cc syringe. Syringes containing RNA and the lipids were connected to a T mixer (PEEK™ 500 μmID junction) using FEP tubing. The outlet from the T mixer was also FEP tubing. The third syringe containing the citrate buffer was connected to a separate piece of FEP tubing. All syringes were then driven at a flow rate of 7 mL/min using a syringe pump. The tube outlets were positioned to collect the mixtures in a 20 mL glass vial (while stirring). The stir bar was taken out and the ethanol/aqueous solution was allowed to equilibrate to room temperature for 1 h. Then, the mixture was loaded in a 5 cc syringe, which was fitted to a piece of FEP tubing and in another 5 cc syringe with equal length of FEP tubing, an equal volume of 100 mM citrate buffer (pH 6) was loaded. The two syringes were driven at 7 mL/min flow rate using a syringe pump and the final mixture collected in a 20 mL glass vial (while stirring). Next, the mixture collected from the second mixing step (liposomes) was passed through a Mustang Q membrane (an anion-exchange support that binds and removes anionic molecules, obtained from Pall Corporation, Ann Arbor, MI, USA). Before passing the liposomes, 4 mL of 1 M NaOH, 4 mL of 1 M NaCl, and 10 mL of 100 mM citrate buffer (pH 6) were successively passed through the Mustang membrane. Liposomes were warmed for 10 min at 37° C. before passing through the filter. Next, liposomes were concentrated to 2 mL and dialyzed against 10-15 volumes of 1×PBS using TFF system before recovering the final product. The TFF system and hollow fiber filtration membranes were purchased from Spectrum Labs and were used according to the manufacturer's guidelines. Polyethersulfone (PES) hollow fiber filtration membranes with a 100 kDa pore size cutoff and 20 cm² surface area were used. For in vitro and in vivo experiments formulations were diluted to the required RNA concentration with 1×PBS.

Calves received 2 mL of each experimental vaccine, administered intramuscularly as 2x 1 mL on each side of the neck. In contrast, the “Triangle 4” vaccine was given as a single 2 mL dose in the neck.

Serum was collected for antibody analysis on days 0, 14, 21, 35, 42, 56, 63, 86, 100, 107, 114, 121, 128, 135, 146, 160, 167, 174, 181, 188, 195, and 202. If an individual animal had a titer below the limit of detection it was assigned a titer of 5 FIG. 14A shows F-specific IgG titers over the first 63 days. The RNA replicon was immunogenic in the cows using both delivery systems, although it gave lower titers than the licensed vaccine. All vaccinated cows showed F-specific antibodies after the second dose, and titers were very stable from the period of 2 to 6 weeks after the second dose (and were particularly stable for the RNA vaccines). The titers with the liposome delivery system were more tightly clustered than with the emulsion.

FIG. 14B shows F-specific serum IgG titers (GMT) over 210 days, and measured values up to day 202 were as follows:

3wp1 2wp2 5wp2 ~9wp2 2wp3 5wp3 8wp3 2wp4 5wp4 8wp4 D0 D21 D35 D56 D86 D100 D121 D146 D160 D181 D202 PBS 5 5 5 5 5 5 5 5 46 98 150 Liposome 5 5 12 11 20 768 428 74 20774 7022 2353 CNE17 5 5 34 46 56 773 538 70 8297 4843 2073 Triangle 4 5 5 1784 721 514 3406 2786 336 13376 4775 2133

The emulsion-adjuvanted vaccine induced a neutralizing response when assayed without complement, with higher titers than Triangle 4 (although more variable). RSV serum neutralizing antibody titers were as follows:

2wp2 5wp2 2wp3 3wp3 4wp3 8wp3 2wp4 3wp4 4wp4 D0 D35 D56 D100 D107 D114 D146 D160 D167 D174 PBS 12 10 10 14 18 20 14 10 10 10 Lipo- 13 10 10 20 13 17 13 47 26 21 some CNE- 10 10 13 28 44 52 14 64 57 40 17 Trian- 12 15 13 39 38 41 13 24 26 15 gle 4

The data from this study provide proof of concept for RNA replicon RSV vaccines in large animals, with two of the five calves in the emulsion-adjuvanted group demonstrating good neutralizing antibody titers after the third vaccination, as measured by the complement-independent HRSV neutralization assay. Although the emulsion-adjuvanted vaccines appear to be more immunogenic than the liposome-adjuvanted vaccines, one complicating factor is that the material used for the second liposome dose was not freshly prepared, and the same lot of RNA showed a decrease in potency in a mouse immunogenicity study. Therefore, it is possible that the liposome-adjuvanted vaccine would have been more immunogenic if fresh material had been used for all vaccinations.

When assayed with complement, neutralizing antibodies were detected in all vaccinated cows. In this assay, all vaccinated calves had good neutralizing antibody titers after the second RNA vaccination regardless of the formulation. Furthermore, both RNA vaccines elicited F-specific serum IgG titers that were detected in a few calves after the second vaccination and in all calves after the third. MF59™-adjuvanted RSV-F was able to boost the IgG response in all previously vaccinated calves, and to boost complement-independent HRSV neutralization titers of calves previously vaccinated with RNA.

Proof of concept for RNA vaccines in large animals is particularly important in light of the loss in potency observed previously with DNA-based vaccines when moving from small animal models to larger animals and humans. A typical dose for a cow DNA vaccine would be 0.5-1 mg (see references 52 and 53) and so it is very encouraging that immune responses were induced with only 66 μg of RNA.

It will be understood that the invention has been described by way of example only and modifications may be made whilst remaining within the scope and spirit of the invention.

TABLE 1 useful phospholipids DDPC 1,2-Didecanoyl-sn-Glycero-3-phosphatidylcholine DEPA 1,2-Dierucoyl-sn-Glycero-3-Phosphate DEPC 1,2-Erucoyl-sn-Glycero-3-phosphatidylcholine DEPE 1,2-Dierucoyl-sn-Glycero-3-phosphatidylethanolamine DEPG 1,2-Dierucoyl-sn-Glycero-3[Phosphatidyl-rac-(1-glycerol . . .) DLOPC 1,2-Linoleoyl-sn-Glycero-3-phosphatidylcholine DLPA 1,2-Dilauroyl-sn-Glycero-3-Phosphate DLPC 1,2-Dilauroyl-sn-Glycero-3-phosphatidylcholine DLPE 1,2-Dilauroyl-sn-Glycero-3-phosphatidylethanolamine DLPG 1,2-Dilauroyl-sn-Glycero-3[Phosphatidyl-rac-(1-glycerol . . .) DLPS 1,2-Dilauroyl-sn-Glycero-3-phosphatidylserine DMG 1,2-Dimyristoyl-sn-glycero-3-phosphoethanolamine DMPA 1,2-Dimyristoyl-sn-Glycero-3-Phosphate DMPC 1,2-Dimyristoyl-sn-Glycero-3-phosphatidylcholine DMPE 1,2-Dimyristoyl-sn-Glycero-3-phosphatidylethanolamine DMPG 1,2-Myristoyl-sn-Glycero-3[Phosphatidyl-rac-(1-glycerol . . .) DMPS 1,2-Dimyristoyl-sn-Glycero-3-phosphatidylserine DOPA 1,2-Dioleoyl-sn-Glycero-3-Phosphate DOPC 1,2-Dioleoyl-sn-Glycero-3-phosphatidylcholine DOPE 1,2-Dioleoyl-sn-Glycero-3-phosphatidylethanolamine DOPG 1,2-Dioleoyl-sn-Glycero-3[Phosphatidyl-rac-(1-glycerol . . .) DOPS 1,2-Dioleoyl-sn-Glycero-3-phosphatidylserine DPPA 1,2-Dipalmitoyl-sn-Glycero-3-Phosphate DPPC 1,2-Dipalmitoyl-sn-Glycero-3-phosphatidylcholine DPPE 1,2-Dipalmitoyl-sn-Glycero-3-phosphatidylethanolamine DPPG 1,2-Dipalmitoyl-sn-Glycero-3[Phosphatidyl-rac-(1-glycerol . . .) DPPS 1,2-Dipalmitoyl-sn-Glycero-3-phosphatidylserine DPyPE 1,2-diphytanoyl-sn-glycero-3-phosphoethanolamine DSPA 1,2-Distearoyl-sn-Glycero-3-Phosphate DSPC 1,2-Distearoyl-sn-Glycero-3-phosphatidylcholine DSPE 1,2-Diostearpyl-sn-Glycero-3-phosphatidylethanolamine DSPG 1,2-Distearoyl-sn-Glycero-3[Phosphatidyl-rac-(1-glycerol . . .) DSPS 1,2-Distearoyl-sn-Glycero-3-phosphatidylserine EPC Egg-PC HEPC Hydrogenated Egg PC HSPC High purity Hydrogenated Soy PC HSPC Hydrogenated Soy PC LYSOPC MYRISTIC 1-Myristoyl-sn-Glycero-3-phosphatidylcholine LYSOPC PALMITIC 1-Palmitoyl-sn-Glycero-3-phosphatidylcholine LYSOPC STEARIC 1-Stearoyl-sn-Glycero-3-phosphatidylcholine Milk Sphingomyelin MPPC 1-Myristoyl,2-palmitoyl-sn-Glycero 3-phosphatidylcholine MSPC 1-Myristoyl,2-stearoyl-sn-Glycero-3-phosphatidylcholine PMPC 1-Palmitoyl,2-myristoyl-sn-Glycero-3-phosphatidylcholine POPC 1-Palmitoyl,2-oleoyl-sn-Glycero-3-phosphatidylcholine POPE 1-Palmitoyl-2-oleoyl-sn-Glycero-3-phosphatidylethanolamine POPG 1,2-Dioleoyl-sn-Glycero-3[Phosphatidyl-rac-(1-glycerol) . . .] PSPC 1-Palmitoyl,2-stearoyl-sn-Glycero-3-phosphatidylcholine SMPC 1-Stearoyl,2-myristoyl-sn-Glycero-3-phosphatidylcholine SOPC 1-Stearoyl,2-oleoyl-sn-Glycero-3-phosphatidylcholine SPPC 1-Stearoyl,2-palmitoyl-sn-Glycero-3-phosphatidylcholine

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The invention claimed is:
 1. A method of eliciting an antibody response against a coronavirus spike polypeptide immunogen by an immune system in a large mammal, the method comprising administering intramuscularly to the large mammal at least two unit doses, each unit dose comprising a composition comprising lipid particles and messenger ribonucleic acid (mRNA) molecules; the at least two unit doses being sequential and administered at least 1 week apart; the administering comprising contacting the composition with skeletal muscle; the mRNA molecules comprising a sequence that encodes the coronavirus spike polypeptide immunogen; each unit dose comprising between 2 μg and 100 μg of the mRNA molecules; the lipid particles comprising: i) a polyethylene glycol-ylated lipid, ii) cholesterol, iii) an anionic phospholipid or a zwitterionic phospholipid, and iv) a cationic lipid; the cationic lipid comprising a tertiary amine; the lipid particles encapsulating at least half of the mRNA molecules; and the large mammal being a human or a cow.
 2. The method of claim/3, the mRNA molecules comprising a 5′ cap nucleoside, a first 5′ ribonucleoside, and a triphosphate bridge; the 5′ cap nucleoside being linked 5′-to-5′ to the first 5′ ribonucleoside by the triphosphate bridge: the 5′ cap nucleoside optionally being a 7-methylguanosine; and the large mammal being the human.
 3. The method of claim 2, the mRNA molecules comprising a modified nucleotide.
 4. The method of claim 3, the modified nucleotide being a modified pyrimidine nucleotide.
 5. The method of claim 4, the lipid particles comprising the zwitterionic phospholipid; and the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine.
 6. The method of claim 5 comprising administering to the human at least three unit doses.
 7. The method of claim 3, the lipid particles comprising the zwitterionic phospholipid; and the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine.
 8. The method of claim 7 comprising administering to the human at least three unit doses.
 9. The method of claim 2, the lipid particles comprising the zwitterionic phospholipid; and the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine.
 10. The method of claim 9 comprising administering to the human at least three unit doses.
 11. The method of claim 1, at least 80% of the lipid particles having diameters from 20 nm to 220 nm.
 12. The method of claim 11, the lipid particles comprising the zwitterionic phospholipid; the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine; and the large mammal being a human.
 13. The method of claim 12 comprising administering to the human at least three unit doses.
 14. The method of claim 1, the lipid particles comprising the zwitterionic phospholipid; the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine; and the large mammal being the human.
 15. The method of claim 14 comprising administering to the human at least three unit doses.
 16. A method of eliciting an antibody response against a coronavirus spike polypeptide immunogen by an immune system in a large mammal, the method comprising administering intramuscularly to the large mammal at least two unit doses, each unit dose comprising a composition comprising lipid particles and mRNA molecules; the at least two unit doses being sequential and administered at least 1 week apart; the administering comprising contacting the composition with skeletal muscle; the mRNA molecules comprising a sequence that encodes the coronavirus spike polypeptide immunogen; each unit dose comprising between 0.5 μg and 1.5 μg of the mRNA molecules per kg of the body mass of the large mammal; the lipid particles comprising: i) a polyethylene glycol-ylated lipid, ii) cholesterol, iii) an anionic phospholipid or a zwitterionic phospholipid, and iv) a cationic lipid; the cationic lipid comprising a tertiary amine; the lipid particles encapsulating at least half of the mRNA molecules; and the large mammal being a human or a cow.
 17. The method of claim 16, the mRNA molecules comprising a 5′ cap nucleoside, a first 5′ ribonucleoside, and a triphosphate bridge; the 5′ cap nucleoside being linked 5′-to-5′ to the first 5′ ribonucleoside by the triphosphate bridge: the 5′ cap nucleoside optionally being a 7-methylguanosine; and the large mammal being the human.
 18. The method of claim 17, the mRNA molecules comprising a modified nucleotide.
 19. The method of claim 18, the modified nucleotide being a modified pyrimidine nucleotide.
 20. The method of claim 19, the lipid particles comprising the zwitterionic phospholipid; and the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine.
 21. The method of claim 20 comprising administering to the human at least three unit doses.
 22. The method of claim 18, the lipid particles comprising the zwitterionic phospholipid; and the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine.
 23. The method of claim 22 comprising administering to the human at least three unit doses.
 24. The method of claim 17, the lipid particles comprising the zwitterionic phospholipid; and the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine.
 25. The method of claim 24 comprising administering to the human at least three unit doses.
 26. The method of claim 16, at least 80% of the lipid particles having diameters from 20 nm to 220 nm.
 27. The method of claim 26, the lipid particles comprising the zwitterionic phospholipid; the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine; and the large mammal being a human.
 28. The method of claim 27 comprising administering to the human at least three unit doses.
 29. The method of claim 16, the lipid particles comprising the zwitterionic phospholipid; the zwitterionic phospholipid being 1,2-distearoyl-sn-glycero-3-phosphocholine; and the large mammal being the human.
 30. The method of claim 29 comprising administering to the human at least three unit doses. 